Power converter

ABSTRACT

An apparatus for power conversion includes a transformation stage for transforming a first voltage into a second voltage. The transformation stage includes a switching network, a filter, and a controller. The filter is configured to connect the transformation stage to a regulator. The controller controls the switching network.

CROSS REFERENCE TO RELATED APPLICATIONS

Under 35 USC 120, this application is a divisional of U.S. application Ser. No. 15/590,562, filed May 9, 2017, which under 35 USC 119, claims the benefit of the priority date of U.S. Provisional Application 62/333,432, filed on May 9, 2016 and U.S. Provisional Application 62/333,402, filed on May 9, 2016, and under 35 USC 120, this application is a continuation-in-part of U.S. application Ser. No. 15/138,692, filed on Apr. 26, 2016, which is a continuation of Ser. No. 14/513,747, filed on Oct. 14, 2014, which is a continuation of U.S. application Ser. No. 13/771,904, filed on Feb. 20, 2013 and issued as U.S. Pat. No. 8,860,396 on Oct. 14, 2014, which is a continuation of international application PCT/US2012/036455, filed on May 4, 2012, which, under 35 USC 119, claims the benefit of the priority dates of U.S. Provisional Application No. 61/482,838, filed May 5, 2011, U.S. Provisional Application No. 61/548,360, filed Oct. 18, 2011, and U.S. Provisional Application No. 61/577,271, filed Dec. 19, 2011, the contents of which are all incorporated herein by reference.

FIELD OF INVENTION

This disclosure relates to power supplies, and in particular to power converters.

BACKGROUND

Many power converters include switches and one or more capacitors that are used, for example, to power portable electronic devices and consumer electronics. Switch-mode power converters regulate the output voltage or current by switching energy storage elements (i.e. inductors and capacitors) into different electrical configurations using a switch network.

Switched-capacitor converters are switch-mode power converters that primarily use capacitors to transfer energy. These converters transfer energy from an input to an output by using switches to cycle a network of capacitors through different topological states. A common converter of this type, known as a “charge pump,” is commonly used to produce the high voltages in FLASH memories and other reprogrammable memories. Charge pumps have also been used in connection with overcoming the nuclear strong force to transform one element into another.

In a switched-capacitor converter, the number of capacitors and switches increases as the transformation ratio increases. Switches in the switch network are usually active devices that are implemented with transistors. The switch network may be integrated on a single or on multiple monolithic semiconductor substrates, or formed using discrete devices. Furthermore, since each switch in a power converter normally carries high current, it may be composed of numerous smaller switches connected in parallel.

SUMMARY

Typical DC-DC converters perform voltage transformation and output regulation. This is usually done in a single-stage converter such as a buck converter. However, it is possible to split these two functions into two specialized stages, namely a transformation stage, such as a switching network, and a separate regulation stage, such as a regulating circuit. The transformation stage transforms one voltage into another, while the regulation stage ensures that the voltage and/or current output of the transformation stage maintains desired characteristics.

In those cases where the transformation stage and the regulating stage are close together, a direct connection is possible. However, in other cases, the regulating stage may be far from the transformation stage. Under these circumstances, it is useful to filter the output of the transformation stage to reduce loss.

In one aspect, the invention features a transformation stage for transforming a first voltage into a second voltage. Such a transformation stage includes a switching network, a filter, and a controller. The filter is configured to connect the transformation stage to a regulator, and the controller controls the switching network.

In some embodiments, the filter includes an LC filter.

In other embodiments, the filter includes an inductance that, in operation at a particular switching frequency, sustains a peak-to-peak voltage ripple and supports an inductor current that passes into a load, the inductor current defining an average inductor current. Among these are embodiments in which the inductance is selected by dividing the peak-to-peak voltage ripple by a product of the average inductor current and the switching frequency multiplied by 13/24.

Some embodiments include the regulating circuit.

Also among the embodiments are those in which the filter is configured to connect the transformation stage to more than one regulator.

Yet other embodiments include plural regulating circuits, wherein the filter connects the transformation stage to all of the regulators.

Also among the embodiments are those in which the transformation stage includes plural switching networks. In these embodiments, the filter connects to all of the switching networks to a regulating circuit.

Other embodiments include those in which the transformation stage includes a plurality of units in series. Each unit includes a switching network in series with a filter.

Typical DC-DC converters perform voltage transformation and output regulation. This is usually done in a single-stage converter such as a buck converter. However, it is possible to split these two functions into two specialized stages, namely a transformation stage, such as a switching network, and a separate regulation stage, such as a regulating circuit. The transformation stage transforms one voltage into another, while the regulation stage ensures that the voltage and/or current output of the transformation stage maintains desired characteristics.

In those cases where the transformation stage and the regulating stage are close together, a direct connection is possible. However, in other cases, the regulating stage may be far from the transformation stage. Under these circumstances, it is useful to filter the output of the transformation stage to reduce loss.

In one aspect, the invention includes an apparatus having phase and stack switches for operating a switched-capacitor converter. The phase and stack switches are on respective first and second dies.

Some embodiments include a first controller that controls the switches on the first die and a second controller that controls switches on the second die. An inter-controller commissure provides a link between the first and second controllers to permit operation of the first switches to depend at least in part on operation of the second switches, and to permit operation of the second switches to depend at least in part on operation of the first switches. Among these are embodiments in which the first controller is on the first die, the second controller is on the second die, and the inter-controller commissure extends between the first die and the second die. Also among the embodiments are those that include a third die and a fourth die. In these embodiments, the first controller is on the third die, the second controller is on the fourth die, and the inter-controller commissure extends between the third die and the fourth die.

In some embodiments, the switched-capacitor converter is a two-phase converter. Some of these embodiments have third and fourth dies. The stack switches comprise first and second sets, each of which is associated with one of the two phases. The first set of stack switches is on the second die and the second set of stack switches is on the fourth die. Meanwhile, the phase switches comprise first and second sets of phase switches, each of which is associated with one of the two phases. The first set of phase switches is on the first die and the second set of phase switches is on the third die.

Also among the embodiments are those that include charge-transfer capacitors connected to the stack switches and to the phase switches. Among these are embodiments having a third die in which the charge-transfer capacitors are integrated. Also among these are embodiments in which the charge-transfer capacitors are discrete capacitors that connect to the first and second dies. In some of these embodiments, the first die and the second die are connected via an inter-die commissure having a length that corresponds to a distance between positive and negative terminals of the charge-transfer capacitors. Also among the embodiments are those that have an interdie commissure connecting the first and second dies, wherein the first and second dies have first terminals for connection to positive terminals of the charge-transfer capacitors, and second terminals for connection to negative terminals of the charge-transfer capacitors, with the first and second terminals and the second terminals being disposed on opposite ends of the interdie commissure, and with the charge-transfer capacitors being oriented such that positive terminals thereof lie closer to the first terminals than they do to the second terminals and negative terminals thereof lie closer to the second terminals than to the first terminals. Also among the embodiments are those in which interdie commissure has first and second regions such that, during operation, the first region carries more current than the second region. In these embodiments, the first region is wider than the second region.

In some embodiments, the charge-transfer capacitors have capacitances that are a function of voltage applied across the charge-transfer capacitors. In operation, the charge-transfer capacitors sustain different maximum voltages. The charge-transfer capacitors are selected such that, when at their respective maximum voltages, the charge-transfer capacitors all have the same capacitance.

Some embodiments include an interdie commissure connecting the first and second dies. As a result of a fold in the interdie commissure, the first and second dies lie on different planes. Other embodiments feature coplanar first and second dies.

Embodiments include those in which the switched-capacitor converter is a multi-phase converter, and the apparatus has a third die. In these embodiments, the phase switches comprise a first set of phase switches associated with a first phase and a second set of phase switches associated with a second phase, with the first set being on the first die and the second set on the second die. Among these are embodiments that have first and second sets of charge-transfer capacitors, with the first set of charge-transfer capacitors being connected between the first die and the second die, and the second set of charge-transfer capacitors being connected between the third die and the second die.

Other embodiments include a substrate and charge-transfer capacitors. In these embodiments, the substrate supports the charge-transfer capacitors, the first die, and the second die. Among these are embodiments in which the device faces of the first and second dies face the substrate, and conducting bumps between the device face and the substrate provide electrical communication between the dies and the charge-transfer capacitors. Also among these are embodiments that have a package, with the first and second dies being in the package and oriented so that they are either coplanar or non-coplanar.

Other embodiments include a substrate, a package, a third die, and charge-transfer capacitors. In these embodiments, the charge-transfer capacitors are integrated into the third die, the substrate supports the package, the package includes the first die, the second die, and the third die, and the first, second, and third dies are distributed among different layers of the package. Among these are embodiments in which the package comprises a first layer and a second layer. In these embodiments, the first and second dies are in the first layer and the third die is in the second layer. Also among these are embodiments in which the package comprises a first layer and a second layer. In these embodiments, the first and third dies are in the first layer and the second die is in the second layer. Also among these are embodiments in which the package comprises a first layer, a second layer, and a third layer. In these embodiments, each layer contains at most one die. In some of these embodiments, the second layer is between the first and third layers, and the third die is in the second layer.

Some embodiments include a substrate that supports a package. The package has an upper layer and a lower layer, with the lower layer being closer to the substrate than the upper layer. The lower layer contains a die and the upper layer contains charge-transfer capacitors. The inductor is on the substrate outside the package. Among these are embodiments in which the die's device face faces the substrate. The apparatus further includes first and second interconnect layers, and electrically conducting bumps. The first interconnect layer connects the charge-transfer capacitors to the die, and the second interconnect layer connects the die to the charge-transfer capacitors and to the electrical bumps. The electrical bumps connect the package with the inductor.

Also among these are embodiments in which a device face of the die faces away from the substrate. These embodiments include a heat sink, thermally-conducting bumps, a first interconnect layer, a second interconnect layer, and electrically-conducting bumps. The first interconnect layer connects the charge-transfer capacitors to the die. The second interconnect layer connects the die to the charge-transfer capacitors and to the electrically-conducting bumps. The electrically-conducting bumps connect the package with the inductor. In these embodiments, the heat sink faces the substrate, and the thermally-conducting bumps connect the heat sink to the substrate. These thermally-conducting bumps carry only heat. They are electrically disconnected from the circuit.

Also among these are embodiments in which a device face of the die faces away from the substrate. In these embodiments, a first interconnect layer connects charge-transfer capacitors to the die, and a second interconnect layer connects the die to the charge-transfer capacitors and to electrically conducting pads. The electrically conducting pads connect the package with the inductor. The thermally-conducting pad connects the heat sink, which faces the substrate, to the substrate. This thermally-conducting pad carries only heat. It is electrically isolated from the inductor, the charge-transfer capacitor, and the die.

Other embodiments also include a substrate that supports a package having upper and lower layers, with the lower layer being closer to the substrate that the upper layer. The inductor is in the package. The lower layer contains a die and upper layer contains charge-transfer capacitors are in the upper layer. Among these are embodiments in which the inductor is disposed in the upper layer. Also among these embodiments are those in which conductive traces around an inductor core in the layer form the inductor.

Among the foregoing embodiments are those in which a device face of the chip faces away from the substrate. In these embodiments, thermally-conducting bumps connect a heat sink to the substrate. These thermally-conducting bumps only carry heat. They are electrically isolated from the die, the charge-transfer capacitors, and the inductor.

Yet other embodiments include regulator switches in the first die.

These and other features of the invention will be apparent from the following detailed description and the accompanying figures, in which:

DESCRIPTION OF THE FIGURES

FIG. 1 shows a power converter with a separable transformation stage and regulation stage;

FIG. 2 shows a power converter similar to that shown in FIG. 1 but with an isolated transformation stage;

FIGS. 3 to 10 show different ways of connecting transformation and regulation stages;

FIG. 11 shows a DC-DC converter with a separate regulating circuit and switching network;

FIG. 12 shows a power converter with a filter between the switching network and the regulation stage;

FIG. 13 shows the power converter of FIG. 12 but without the regulation stage;

FIG. 14 explicitly shows control circuitry associated with a converter as shown in FIG. 11;

FIG. 15 shows details of the control circuitry shown in FIG. 14;

FIG. 16 shows signals present during operation of the control circuitry of FIG. 15;

FIG. 17 is a close-up of four signals from FIG. 12 showing the dead-time interval;

FIG. 18 shows details of switch layout in a converter similar to that shown in FIG. 1;

FIGS. 19 and 20 show dependence of switching period and peak-to-peak ripple as a function of output load current in two embodiments of the control circuitry as shown in FIG. 14;

FIG. 21 shows a multi-phase converter similar to that shown in FIG. 14;

FIGS. 22 and 23 show signals present during operation of the control circuitry of FIG. 21;

FIG. 24 shows another power converter similar to that shown in FIG. 14 but with one regulator and plural switching networks;

FIG. 25 shows another power converter similar to that shown in FIG. 14 but with one switching network and plural regulators;

FIG. 26 shows a power converter similar to that shown in FIG. 25 but with a filter between the switching network and the regulators;

FIG. 27 shows a power converter similar to that shown in FIG. 24 but with a filter between the switching networks and the regulator;

FIG. 28 shows a bidirectional version of FIG. 11;

FIGS. 29-30 show DC-DC converters with alternate configurations of regulating circuits and switching networks;

FIG. 31 shows a DC-DC converter like that shown in FIG. 30 with a controller;

FIG. 32 shows another configuration of a DC-DC converter;

FIG. 33 shows a particular implementation of the power converter illustrated in FIG. 32;

FIG. 34 shows an embodiment with multiple regulating circuits;

FIG. 35 shows an RC circuit;

FIG. 36 shows a model of a switched capacitor DC-DC converter;

FIG. 37 shows an isolated variant of FIG. 36;

FIG. 38 shows output resistance of a switched-capacitor network as a function of switching frequency;

FIGS. 39-40 show a series-parallel SC converter operating in charge phase and discharge phase respectively;

FIG. 41 shows a series pumped symmetric cascade multiplier with diodes;

FIG. 42 shows a parallel pumped symmetric cascade multiplier with diodes;

FIG. 43 shows charge pump signals;

FIG. 44 shows a two-phase symmetric series pumped cascade multiplier with switches;

FIG. 45 shows a two-phase symmetric parallel pumped cascade multiplier with switches;

FIG. 46 shows four cascade multipliers along with corresponding half-wave versions;

FIG. 47 shows the circuit of FIG. 35 with an auxiliary converter used to reduce loss associated with charging a capacitor;

FIG. 48 shows an implementation of the circuit of FIG. 47;

FIG. 49 shows a cascade multiplier with clocked current sources;

FIG. 50 shows output impedance of a switched-capacitor converter as a function of frequency;

FIGS. 51, 52, and 53 show clocked current sources;

FIG. 54 shows a cascade multiplier with the clocked current source of FIG. 52;

FIG. 55 shows an embodiment of the circuit shown in FIG. 54;

FIG. 56 shows current and voltage at selected locations in the circuit of FIG. 55;

FIG. 57 shows a particular implementation of the DC-DC converter illustrated in FIG. 28 with a full-wave adiabatically charged switching network;

FIG. 58 shows the DC-DC converter illustrated in FIG. 54 during phase A;

FIG. 59 shows the DC-DC converter illustrated in FIG. 54 during phase B;

FIG. 60 shows various waveforms associated with a 4:1 adiabatically charged converter;

FIG. 61 shows adiabatic charging of series connected stages;

FIG. 62 shows a particular implementation of the power converter illustrated in FIG. 61;

FIG. 63 shows adiabatic charging of series connected stages with filters between each stage;

FIG. 64 shows a particular implementation of the power converter illustrated in FIG. 63;

FIG. 65 shows an AC-DC power converter architecture;

FIG. 66 shows an AC voltage rectified using a reconfigured switched-capacitor stage;

FIG. 67 shows an embodiment of the AC-DC power converter architecture in FIG. 65, which includes an AC switching network;

FIG. 68 shows a particular implementation of the AC-DC converter illustrated in FIG. 67;

FIGS. 69-70 shows the AC-DC converter in FIG. 68 during the positive and negative portions of the AC cycle respectively;

FIG. 71 shows an AC-DC power converter architecture with power-factor correction;

FIG. 72 shows a converter having an isolated controller;

FIG. 73 shows an alternative architecture of the converter in FIG. 72 where the switching network is loaded by an LC filter;

FIG. 74 shows a converter in which a control signal for the regulating circuit is isolated from a control signal for the switching network;

FIG. 75 shows a configuration of FIG. 29 with an isolated controller as shown in FIG. 74;

FIG. 76 shows a configuration of FIG. 32 with an isolated controller as shown in FIG. 74;

FIG. 77 shows an implementation of the rectifier shown in FIG. 65;

FIG. 78 shows an alternative implementation of the rectifier shown in FIG. 65;

FIG. 79 shows an EMI filter from the rectifiers shown in FIGS. 77 and 78;

FIG. 80 shows an alternative EMI filter from the rectifiers shown in FIGS. 77 and 78;

FIG. 81 shows an AC bridge for use in the embodiments shown in FIGS. 77 and 78;

FIG. 82 shows one transformation stage driving two parallel regulation stages;

FIG. 83 shows a transformation stage providing filtered output to parallel regulating stages;

FIGS. 84 and 85 show implementations of the DC-DC converter illustrated in FIG. 28;

FIGS. 86 and 87 show implementations of the DC-DC converter illustrated in FIG. 30;

FIGS. 88 and 89 show implementations of the DC-DC converter illustrated in FIG. 29;

FIGS. 90 and 91 show implementations of the DC-DC converter illustrated in FIG. 32;

FIG. 92 shows a switching network implemented as a stack of layers;

FIGS. 93-96 are cross-sections of the stack in FIG. 92 with different orders of passive and active layers;

FIGS. 97-100 show different locations of active and passive device faces for the two-layer stack shown in FIG. 93;

FIGS. 101-104 show different locations of active and passive device faces for the two-layer stack shown in FIG. 94;

FIG. 105 shows an implementation of FIG. 93 in which the passive device layer has a planar capacitor;

FIG. 106 shows an implementation of FIG. 93 in which the passive device layer has a trench capacitor;

FIG. 107 shows an implementation of FIG. 105 with wafer-to-wafer bonding instead of die-to-die bonding;

FIG. 108 shows an implementation of FIG. 107 but with the device face of the active layer being its upper face instead of its lower face;

FIG. 109 shows three partitioned current paths of a switching network;

FIG. 110 shows an active layer with eight switches superimposed on eight capacitors on a passive layer below it;

FIG. 111 shows one of the switches in FIG. 110 that has been partitioned into nine partitions;

FIG. 112 shows a divided switching but not partitioned switch and capacitor;

FIG. 113 shows a partitioned switch and capacitor;

FIG. 114 shows a capacitor partitioned in two dimensions;

FIG. 115 is a functional block diagram of one embodiment of the switching network shown in FIGS. 13 and 12;

FIG. 116 shows an exemplary circuit of the switching network shown in FIG. 115;

FIG. 117 shows a particular terminal layout for implementation of the switching network shown in FIG. 115;

FIG. 118 is a functional block diagram of another embodiment of the switching network shown in FIGS. 13 and 12;

FIG. 119 shows an exemplary circuit of the switching network shown in FIG. 118;

FIG. 120 shows a particular terminal layout for implementation of the switching network shown in FIG. 118;

FIG. 121 shows the terminal layout for the phase-die in FIG. 120 with the locations of the phase switches in FIG. 119 explicitly shown therein;

FIG. 122 is a functional block diagram of another embodiment of the switching network shown in FIGS. 13 and 12, but the inclusion of switches for a regulator to which the switching network is to be connected;

FIG. 123 shows a substrate bearing components for implementing a switching network;

FIG. 124 shows the phase die and stack die of FIG. 123 within the same package;

FIG. 125 shows a stacked phase die and stack die;

FIG. 126 shows the circuit of FIG. 124 but with the charge-transfer capacitors now being on their own capacitor die and included on their own layer in the package.

FIG. 127 shows the circuit of FIG. 124 but with the charge-transfer capacitors now being on their own capacitor die, included in the package, and occupying the same layer as the phase die.

FIG. 128 shows a package in which the charge-transfer capacitor die is sandwiched between the phase die and the stack die; and

FIGS. 129-133 show embodiments of a circuit that also includes an inductor.

DETAILED DESCRIPTION

Some power converters carry out both regulation and transformation with a limited number of circuit components by comingling these functions into a single stage. As a result, certain components are used both for regulation and transformation. Sometimes the regulation stage is referred to as a regulating circuit and the transformation stage is referred to as a switching network. As used herein, these terms mean the same thing.

FIG. 1 shows a modular multi-stage power converter that separates the converter's transformation and regulation functions. These functions are no longer accomplished together as they would be in a single-stage converter design. As a result, in a multi-stage power converter, as shown in FIG. 1, it is possible to optimize a transformation stage and a regulation stage for their specific functions. The transformation stage and the regulation stage can be treated as either independent entities or coupled entities.

In the power converter of FIG. 1, a transformation stage receives an input voltage V_(IN) across its two input terminals and outputs an intermediate voltage V_(X) across its two output terminals at a fixed voltage conversion ratio. Therefore, the intermediate voltage V_(X) changes in response to changes in the input voltage V_(IN). The transformation stage is thus regarded as “variable” if the voltage conversion ratio can be varied. However, it is not required that a transformation stage be “variable”.

In the particular embodiment shown in FIG. 1, there exists an electrical connection between the transformation stage's negative input terminal and its negative output terminal. In this configuration, the transformation stage is said to be “non-isolated.” In contrast, the embodiment shown in FIG. 2, no such connection exists between the transformation stage's negative input and its negative output. An example of such a transformation stage is shown in FIG. 37 with a voltage conversion ratio of N₁:N₂.

In general, two functional components of a circuit or system are said to be isolated, in a galvanic sense, if no direct conduction path exists between those two components, and yet energy and information can still be communicated between those components. The communication of such energy and information can be carried out in a variety of ways that do not require actual current flow. Examples include communication via waves, whether electromagnetic, mechanical, or sonic. Electromagnetic waves in this context include waves in the visible range, as well as just outside the visible range. Such communication can also be implemented via static or quasi-static electric or magnetic fields, capacitively, inductively, or by mechanical means.

Galvanic isolation is particularly useful for cases in which the two functional components have grounds that are at different potentials. Through galvanic isolation of components, it is possible to essentially foreclose the occurrence of ground loops. It is also possible to reduce the likelihood that current will reach ground through an unintended path, such as through a person's body.

The transformation stage efficiently provides an intermediate voltage V_(X) that differs from the input voltage V_(IN) and that varies over a much smaller range than the input voltage V_(IN). In practice, the intermediate voltage V_(X) varies during operation if there are changes at either the input or output of the transformation stage. These variations require correction to achieve the desired output voltage V_(O). It is for this reason that a regulation stage is necessary. As shown in FIGS. 1 and 28, a regulation stage receives the intermediate voltage V_(X) across its input terminals and provides a regulated voltage V_(O) across its output terminals.

The architecture shown in FIG. 1 is flexible enough to permit designs with different requirements. For example, if magnetic isolation is required, a magnetic isolated fly-back converter can be used. Designs that require multiple regulated output voltages can be accomplished by using two separate regulation stages and a single transformation stage.

The architecture shown in FIG. 1 in effect creates a modular architecture for power converters in which fundamental building blocks can be mixed and matched in a variety of ways to achieve particular goals.

FIGS. 3-10 are block diagrams showing different ways to arrange the transformation stage and the regulation stage relative to a source or a load. The fact that these can even be represented as block diagrams at all stems from the modularity of the architecture. Such modularity is not present in a conventional single-stage converter. In such a converter, the functions of regulation and transformation are so intimately comingled that it is not possible to extract two separate circuits and to say that one carries out regulation and the other carries out transformation. Instead, in a conventional converter, if one attempts to extract two circuits, one of which is a regulator and the other of which is a voltage transformer, the usual result is two circuits that do not work.

FIG. 3 shows a generic architecture in which a pair of transformation stages sandwiches a regulation stage. Each transformation stage includes one or more switched-capacitor networks. Similarly, each regulation stage includes one or more regulating circuits. It is also possible to have more than one source and more than one load. The double-headed arrows in FIG. 3 and in other figures indicate bidirectional power flow.

FIG. 4 shows a source-regulating configuration in which power flows from a source to a transformation stage. The transformation stage then provides the power to a regulation stage, which then passes it to a load. Thus, in this configuration, the load ultimately receives power from the regulation stage.

In contrast, FIG. 5 shows a load-regulating configuration. In a load-regulating configuration, power flows from a source to a regulation stage, which then regulates it and passes it to a transformation stage. In this embodiment, the load receives power directly from the transformation stage instead of directly from the regulation stage.

FIG. 6 shows a reverse source-regulating configuration similar to that shown in FIG. 4, but with power flowing in the opposite direction.

FIG. 7 shows a reverse load-regulating configuration similar to that shown FIG. 5, but with power flowing in the other direction.

In the embodiments shown in FIGS. 8 and 9, two transformation stages bracket a regulation stage. These are distinguished by direction of current flow. FIG. 8 shows a source/load-regulating configuration in which power flows from the source to the load via a first transformation stage, a regulation stage, and a second transformation stage, and FIG. 9 shows a reverse source/load-regulating configuration in which power flows from the load to the source via a first transformation stage, a regulation stage, and a second transformation stage.

In another embodiment, shown in FIG. 10, several regulating circuits rely on the same switched-capacitor converter. Note that of the three power paths, a first and second power path are in the load-regulating configuration whereas the third power path is in the source/load-regulating configuration. An embodiment having several regulating circuits is particularly useful since it enables different output voltages to be provided to different loads.

FIG. 11 shows a power converter 10 assembled by combining two modules using the principles suggested by FIG. 1. The illustrated power converter 10 includes a switching network 12A, a voltage source 14, a regulating circuit 16A, and an inter-module link 11A that connects an output of the switching network 12A to an input of the regulating circuit 16A. A load 18A connects to an output of the regulating circuit 16A. Power flows between the voltage source 14 and the load 18A in the direction indicated by the arrows. To simplify representation, the separation of the connection into positive and negative lines has been omitted.

In the embodiment shown in FIG. 11, the regulating circuit 16A can be at some distance from the switching network 12A. In such cases, it is useful to include a filter at the output of the switching network 12A.

FIG. 12 shows a power converter 10 that, like the embodiment shown in FIG. 11, has a voltage source 14 that provides a first voltage V₁ to a switching network 12A. However, in this embodiment, the switching network 12A provides a second voltage V₂ to an inductance L₁. In the illustrated embodiment, there is also a capacitance C₁ across a load 18A. The inductance L₁ and the capacitance C₁ together define an LC filter that outputs a third voltage V₃ that ultimately makes its way to the regulating circuit 16A shown in FIG. 11. The regulating circuit 16A adjusts the unregulated third voltage V₃ to yield a regulated fourth voltage V₄, which it then provides to the load 18A.

An alternative embodiment, shown in FIG. 13, connects the third voltage V₃ directly to the load 18A. In this embodiment, the filter formed by the combination of the capacitor C₁ and inductor L₁ regulates the third voltage V₃ without the need for a regulating circuit 16A. The various configurations shown above have switches that need to be opened and closed at certain times. Thus, they all implicitly require one or more controllers to provide control signals that open and close these switches. The structure and operation of such a controller 20A is described in connection with FIGS. 14-23.

FIG. 14 shows the power converter 10 of FIG. 11, but with a controller 20A explicitly shown. The controller 20A features three sensor inputs: an intermediate-voltage input for an intermediate voltage V_(X), an output-voltage input for the output voltage V_(O), and an optional input-voltage input for the input voltage V_(IN). The controller 20A has two other inputs: a clock input to receive a clock signal CLK and a reference input to receive a reference voltage V_(REF). Examples of the various signals above, as well as others to be described below, can be seen in FIG. 16.

Based on the aforementioned inputs, the controller 20A provides a first control signal ϕ to control switches in the switched-capacitor element 12A and a second control signal PWM to control switching of the regulating circuit 16A. The first control signal is a two-dimensional vector having first and second complementary phases ϕ, ϕ. In some embodiments, the first control signal is a vector having higher dimensionality. In the illustrated embodiment, the second control signal PWM is a scalar. However, in multi-phase embodiments described below, the second control signal PWM is also a vector.

The controller 20A relies on the clock signal CLK and the intermediate voltage V_(X) to set the period of the second control signal PWM for controlling the regulating circuit 16A. A comparison between the reference voltage V_(REF) and the output voltage V_(O) provides a basis for controlling the output voltage V_(O).

The controller 20A synchronizes operation of the switching network 12A and the regulating circuit 16A. It does so by synchronizing a ripple on the intermediate voltage V_(X) with the second control signal PWM. Such synchronization relaxes the requirement of running the regulation circuit 16A at a significantly higher frequency than the switching network 12A in an attempt to achieve effective feed-forward control.

The control method described herein also avoids glitches inherent in changing the switching frequency of the switching network 12A. It does so by making use of a regulating circuit 16A that draws discontinuous input current. An example of such a regulating circuit 16A is one that uses a buck converter.

Referring now to FIG. 15, the controller 20A has a switched-capacitor section 301 and a regulator section 302. These can be on the same die or on different dies.

The switched-capacitor section 301 outputs the first control signal ϕ. The complementary first and second phases ϕ, ϕ that make up the first control signal are shown as the last two traces in FIG. 16.

The switched-capacitor section 301 has an undershoot limiter 36 that receives the input voltage V_(IN) and the intermediate voltage V_(X). Based on these, the undershoot limiter 36 determines a trigger level V_(X_L). The trigger level V_(X_L) is shown as a dashed horizontal line superimposed on the sixth trace on FIG. 16. The switched capacitor section 301 ultimately uses this trigger level V_(X_L) to determine when it is time to generate the first control signal 41). The details of how this is done are described below.

After having generated the trigger level V_(X_L) based on the input voltage V_(IN) and the intermediate voltage V_(X), the undershoot limiter 36 provides it to a first comparator 35. The first comparator 35 then compares the trigger level V_(X_L) with the intermediate signal V_(X). Based on the comparison, the first comparator 35 provides a first trigger signal to a first control signal generator 34, which ultimately outputs the first control signal ϕ.

The switched capacitor section 301 thus forms a first feedback loop that manipulates the first control signal ϕ in an effort to control the intermediate voltage V_(X) based on the combination of the intermediate voltage V_(X) and the input voltage V_(IN).

The first control signal generator 34 does not generate the first control signal ϕ immediately. Instead, the first control signal generator 34 waits for an opportune moment to do so. The occurrence of this opportune moment depends on what the regulator section 302 is doing.

While the switched capacitor section 301 is busy providing the first trigger signal to the first control signal generator 34, the regulator section 302 is also busy generating the second control signal PWM. The regulator section 302 begins this process with a voltage compensator 31 that receives a voltage output V_(O) and a reference voltage V_(REF). From these, the voltage compensator 31 generates an error voltage V_(ERR).

Some implementations of the voltage compensator 31 include linear voltage-mode control and peak current-mode control. However, other modes are possible. Assuming linear voltage-mode control for the regulation circuit 16A, the voltage compensator 31 compares the output voltage V_(O) of the power converter 10 with a reference voltage V_(REF) and provides an error signal V_(ERR) to a second comparator 32. This error signal V_(ERR) is shown in FIG. 16 superimposed on a serrated waveform V_(SAW) on the second trace shown in FIG. 16.

The regulator section 302 thus forms a second feedback loop that manipulates the second control signal PWM in an effort to control the output voltage V_(O) based on the combination of a reference signal V_(REF) and the output voltage V_(O). However, for reasons discussed in more detail below, the switched capacitor section 301 and the regulator section 302 do not operate independently. Instead, the controller 20A synchronizes their operation.

To provide a basis for such synchronization, the regulator section 302 includes a saw-tooth generator 30. The saw-tooth generator 30 generates the serrated waveform V_(SAW) based on a clock signal CLK and the intermediate voltage V_(X). This serrated waveform V_(SAW) ultimately provides a way to synchronize the first control signal ϕ and the second control signal PWM.

The second comparator 32 compares the error voltage V_(ERR) with the serrated waveform V_(SAW) and outputs a second trigger signal based on this comparison. As shown in FIG. 16, the second control signal PWM changes state in response to a change in the sign of the difference between the error voltage V_(ERR) and the serrated waveform V_(SAW). Since the serrated waveform V_(SAW) is ultimately based on the intermediate voltage V_(X), this provides a basis for synchronizing the operation of the switched-capacitor section 301 and the regulator section 302.

The second control signal generator 33 receives the second trigger signal from the second comparator 32 and uses it as a basis for generating the second control signal PWM.

This second control signal PWM ultimately serves as a gate drive to actually drive the gate of a transistor that implements a main switch 152 in a regulating circuit 16A, details of which are seen in FIG. 18. This main switch 152 ultimately controls an inductor voltage V_(L) and an inductor current IL across and through an inductor 154 within the regulating circuit 16A, as shown by the fourth and fifth traces in FIG. 16.

The particular configuration shown illustrates feed-forward control of the regulation circuit 16A implemented in the saw-tooth generator 30. However, such control could also be implemented in the voltage compensator 31.

The switched-capacitor section 301 implements a hysteretic control system in which a controlled variable, namely the intermediate voltage V_(X), switches abruptly between two states based upon a hysteresis band. The intermediate voltage V_(X) is a piecewise linear approximation of a serrated waveform.

Synchronization between the regulator section 302 and the switched capacitor section 301 is important to enable the dead-time interval of the switching network 12A to occur when no current is being drawn by the regulating circuit 16A.

In a practical switching network 12A, the first control signal ϕ will actually cycle through three states, not just two. In the first state, the first control signal ϕ opens a first set of switches and closes a second set of switches. In the second state, the first control signal ϕ closes the first set of switches and opens the second set of switches.

A practical difficulty that arises is that switches cannot open and close instantly. Nor can they be guaranteed to operate simultaneously. Thus, the first control signal ϕ cycles through a third state, which lasts for a dead-time interval DT. During this third state, all switches open. This minimizes the unpleasant possibility that a switch in the second set will not have opened by the time the switches in the first set have closed.

Meanwhile, certain regulating circuits 16A, such as buck converters and the like, draw input current discontinuously. In particular, such regulating circuits 16A have short intervals during which they are drawing zero current.

The controller 20A avoids glitches by synchronizing the operation of the switching network 12A and the regulating circuit 16A such that the regulating circuit 16A draws zero current during the dead-time interval DT.

A further benefit of such synchronization is the ability to cause switches in the switching network 12A to change state when there is no current flowing through them. This reduces commutation losses. Causing the dead-time interval DT to occur when the regulating circuit 16A is not drawing current, and causing switches in the switching network 12A to only change state at the beginning and the end of the dead-time interval DT thus ensures zero-current switching, as shown in FIG. 17.

In operation, the regulator section 302 and the switched capacitor section 301 cooperate to ensure that the length of one cycle of the first control signal ϕ will be equal to an integral number of cycles of the second control signal PWM. In FIG. 16, this constraint is met because the one cycle of the first control signal ϕ is equal to an integral number of cycles of the second control signal PWM.

The first control signal generator 34 receives a first trigger signal from the first comparator 35 indicating that the intermediate voltage V_(X) has fallen below the trigger level V_(X_L). However, as alluded to above, the first control signal generator 34 does not act immediately. Instead, it waits until there is an opportune time to make a state change. Meanwhile, as the first control signal generator 34 waits, the intermediate voltage V_(X) continues to fall, as shown in FIG. 16.

As shown in FIG. 16, by the time the first control signal generator 34 acts, the intermediate voltage will already have fallen to an undershoot ΔV_(d) below the trigger level V_(X_L). In most cases, the undershoot ΔV_(d) is small and capped by an undershoot cap of ½ΔV_(X), which only occurs when the switching frequency of the regulator section 302 and the switched capacitor section 301 are equal. This undershoot cap depends on load current and input voltage V_(IN).

Large variations in undershoot ΔV_(d) are undesirable because they stress the regulating circuit 18A. The undershoot limiter 36 selects a suitable trigger level V_(X_L) to limit this undershoot ΔV_(d) by indirectly controlling the undershoot cap ½ΔV_(X). The undershoot limiter 36 uses the intermediate voltage V_(X) and the input voltage V_(IN) to select an appropriate value of the trigger level V_(X_L).

FIG. 17 shows a close up of selected waveforms in FIG. 16 at a scale that is actually large enough to show a dead-time interval DT between the two phases ϕ, ϕ that make up the first control signal ϕ. To assist in discussion, it is useful to consider the circuit shown in FIG. 18, which was introduced earlier in a discussion of the function of the second control signal PWM.

FIG. 18 shows a first set of switches 141, 143, 146, 148, which is controlled by the first phase ϕ, and a second set of switches 142, 144, 145, 147, which is controlled by the second phase ϕ. FIG. 18 also shows the main switch 152 that connects the regulating circuit 16A to the switching network 12A. The main switch 152 has already been discussed above.

During this dead-time interval DT, the phases ϕ, ϕ open all switches 141, 143, 146, 148, 142, 144, 145, 147. This dead-time interval DT must occur while the main switch 152 is open. This requirement sets a maximum possible duty cycle D_(max) for the regulating circuit 16A during the switching transition of the first control signal ϕ:

$D_{\max} = \frac{T_{sw} - {DT}}{T_{sw}}$

As is apparent from the above relationship, the dead-time DT places a limit on the maximum possible duty cycle D_(max). It is therefore desirable to reduce the dead-time DT as much as possible to increase the range of possible transformation ratios for the regulating circuit 16A.

For many practical power converters, a desire for electromagnetic compatibility dictates that the regulating circuit 16A should operate at a constant switching frequency. In these cases, the above constraint on the maximum possible duty cycle D_(max) is not overly burdensome, especially, if the feed-back controller for the regulation circuit 16A would otherwise have a maximum duty cycle requirement.

The control strategy as described above and implemented by the controller 20A in FIG. 15 is one of many possible implementations. In general, the switching frequency for switches 141, 143, 146, 148, 142, 144, 145, 147 in the switching network 12A will change in discrete steps as the load current of the power converter 10 varies.

FIG. 19 shows how the output current affects both the period with which the switches 141, 143, 146, 148, 142, 144, 145, 147 of the switching network 12A change state and the corresponding ΔV_(X) ripple.

For this particular control strategy, the ripple magnitude ΔV_(X) varies as a function of load current. In particular, the ripple magnitude ΔV_(X) defines a serrated waveform having a peak-to-peak amplitude that decreases with load current. As the load current approaches zero, the peak-to-peak amplitude approaches half of the maximum peak-to-peak amplitude. With a few modifications to the controller, it is also possible to get the ΔV_(X) ripple to approach the maximum peak-to-peak amplitude as the load current approaches zero, as shown in FIG. 20.

As is apparent from both FIGS. 19 and 20, as the load current increases, the switching period for the switches 141, 143, 146, 148, 142, 144, 145, 147 stays the same for a range of output currents. Within this range of output currents, the converter relies on the regulating circuit 16A to make up the difference between the voltage that the switching network 12A provides whatever voltage is required. At some point, the regulating circuit 16A can no longer make the necessary correction. At that point, the period takes a step down.

The controller 20A shown in FIG. 14 is a single-phase converter. As such, the first control signal ϕ is a two-dimensional vector and the second control signal PWM is a scalar. In the case of an N-phase converter, the first control signal ϕ is a 2N-dimensional vector and the second control signal PWM is an N-dimensional vector having components PWM₁, PWM₂, . . . PWM_(n) that are phase shifted relative to each other. Typically, the phase shift between these components is 360/N degrees.

FIG. 21 shows an example of an N-phase converter having plural regulation circuits 16A, 16B. Each regulation circuit 16A, 16B has a corresponding switching network 12A, 12B. Each regulation circuit 16A, 16B is also driven by its own control signal, hence the need for an N-dimensional second control signal PWM. Each switching network 12A, 12B is driven by a pair of phases, hence the need for a 2N-dimensional first control signal.

An N-phase controller 20A controls the N-phase converter. The N-phase controller 20A is similar to the single-phase controller in FIG. 14 but with additional inputs for the N intermediate voltages V_(X1), V_(X2), . . . V_(XN).

FIG. 22 shows waveforms similar to those shown in FIG. 16 but for a three-phase version of the controller shown in FIG. 14.

As shown in FIG. 22, the second control signal PWM consists of second control signal elements PWM₁, PWM₂, PWM₃ that are separated from each other by a delay time that corresponds to a 120° phase shift between them. The three intermediate voltages V_(X1), V_(X2), V_(X3) are shifted from each other by an integer multiple of this delay time. In FIG. 22, the integer is unity. However, as shown in FIG. 23, other integers are possible.

Because the periods of the intermediate voltages V_(X1), V_(X2), V_(X3) are longer than those of the second control signal elements PWM₁, PWM₂, PWM₃, shifting them by the delay time will not cause them to be 120 degrees out of phase with each other. In fact, because their period is so much longer, a shift by this delay time only causes a very small phase shift in the intermediate voltages V_(X1), V_(X2), V_(X3).

FIG. 23 shows an alternative method of operation similar to that shown in FIG. 22, but with the intermediate voltages V_(X1), V_(X2), V_(X3) having been shifted by a larger multiple of the delay time. This results in a more significant phase shift between the intermediate voltages V_(X1), V_(X2), V_(X3), a result of which is a reduced ripple in the output voltage V_(O).

A multi-phase controller 20A for controlling the N-phase converter shown in FIG. 21 can be thought of as N single-phase controllers 20A as shown in FIG. 15 operating in parallel but with a specific phase relationship between them. A multi-phase controller 20A would thus look very similar to the one in FIG. 15, but with an additional input and output signals. In general, the intermediate voltages (V_(X1), V_(X2), . . . V_(XN)) and the output voltage V_(O) are required for proper operation of the controller 20A.

FIG. 24 shows a converter similar to that shown in FIG. 21, but having only one regulation circuit 16A that is connected to plural switching networks 12A, 12B. Since there is only one regulation circuit 16A, only a 1-dimensional second control signal PWM is required. Each switching network 12A, 12B is driven by a pair of phases, hence the need for a 2N-dimensional first control signal.

FIG. 25 shows a converter that is essentially the converse of FIG. 24. In FIG. 25, the converter has plural regulation circuits 16A, 16B, all of which are coupled to the same switching network 12A. Each regulation circuit 16A, 16B is driven by its own control signal, hence the need for an N-dimensional second control signal PWM. The sole switching network 12A is driven by a pair of phases, hence the need for a 2-dimensional first control signal.

FIG. 26 shows a converter similar to that shown in FIG. 25, but with an inductance L₁ connected to both the output of the switching network 12A and to the inputs of the regulating circuits 16A,16B. A grounded capacitor C₁ provides a place to store excess charge during operation. The N-phase controller 20A observes both a switching-network's output voltage V_(Y) and a regulating circuits' input voltage V_(X).

FIG. 27 shows a converter similar to that shown in FIG. 24 but with an inductance L₁ . . . L_(N) connected to the outputs of each of the switching networks 12A, 12B and to the input of the regulating circuit 16A. A grounded capacitor C₁ provides a place to store excess charge during operation. The N-phase controller 20A uses the switching-networks' output voltages V_(Y1) . . . V_(YN) and the regulating circuit's input voltage V_(X) to generate suitable control signals.

In FIG. 14, a non-capacitive regulating circuit 16A loads down the switching network 12A. This regulating circuit 16A is switched at a high frequency. The components from the high-frequency switching of the regulating circuit 16A are ultimately superimposed on the lower frequency serrated waveform of the intermediate voltage V_(X), as shown in sixth trace on FIG. 16. The duty cycle of the saw-tooth approximation waveform depends on the topology of the switching network 12A. In general, the frequency of the complementary switching-network control signals varies with changes in response to changes in the slope of the intermediate signal. These changes, in turn, arise as a result of changes in the power converter's operating point.

The switching network 12A and the regulating circuit 16A are essentially modular and can be mixed and matched in a variety of different ways. As such, the configuration shown in FIG. 11 represents only one of multiple ways to configure one or more switching networks 12A with one or more regulating circuits 16A to form a multi-stage converter 10.

For example, FIG. 28 shows a bidirectional version of FIG. 11 in which power can flow either from a voltage source 14 to a load 18A or from the load 18A to the voltage source 14 as indicated by the arrows.

There are two fundamental elements described in connection with the following embodiments: switching networks 12A and regulating circuits 16A. Assuming series connected elements of the same type are combined, there are a total of four basic building blocks. These are shown FIGS. 28, 29, 30, and 32. The power converters disclosed herein include at least one of the four basic building blocks. More complex converter can be realized by combining the fundamental building blocks.

The first building block, shown in FIG. 28, features a switching network 12A whose output connects to an input of a regulating circuit 16A. The second building block, shown in FIG. 29, features a first switching network 12A whose output connects to a regulating circuit 16A via a first intermodule link 11A, an output of which connects to an input of a second switching network 12B via a second intermodule link 11B. In the third building block shown in FIG. 30, an output of a regulating circuit 16A connects to an input of a switching network 12A via an intermodule link 11B. A fourth building block, shown in FIG. 33, features a first regulating circuit 300A having an output that connects to an input of a first switching network 200, an output of which connects to an input of a second regulating circuit 300B.

Additional embodiments further contemplate the application of object-oriented programming concepts to the design of power converters by enabling switching networks 12A and regulating circuits 16A to be “instantiated” in a variety of different ways so long as their inputs and outputs continue to match in a way that facilitates modular assembly of power converters having various properties.

The switching network 12A in many embodiments is instantiated as a switched-capacitor network. Among the more useful switched capacitor topologies are: Ladder, Dickson, Series-Parallel, Fibonacci, and Doubler, all of which can be adiabatically charged and configured into multi-phase networks. A particularly useful switching capacitor network is an adiabatically charged version of a full-wave cascade multiplier. However, diabatically charged versions can also be used.

As used herein, changing the charge on a capacitor “adiabatically” means causing an amount of charge stored in that capacitor to change by passing the charge through a non-capacitive element. A positive adiabatic change in charge on the capacitor is considered adiabatic charging while a negative adiabatic change in charge on the capacitor is considered adiabatic discharging. Examples of non-capacitive elements include inductors, magnetic elements, resistors, and combinations thereof.

In some cases, a capacitor can be charged adiabatically for part of the time and diabatically for the rest of the time. Such capacitors are considered to be adiabatically charged. Similarly, in some cases, a capacitor can be discharged adiabatically for part of the time and diabatically for the rest of the time. Such capacitors are considered to be adiabatically discharged.

Diabatic charging includes all charging that is not adiabatic and diabatic discharging includes all discharging that is not adiabatic.

As used herein, an “adiabatically charged switching network” is a switching network having at least one capacitor that is both adiabatically charged and adiabatically discharged. A “diabatically charged switching network” is a switching network that is not an adiabatically charged switching network.

The regulating circuit 16A can be instantiated as any converter with the ability to regulate the output voltage. A buck converter for example, is an attractive candidate due to its high efficiency and speed. Other suitable regulating circuits 16A include boost converters, buck/boost converters, fly-back converters, forward converters, half-bridge converters, full-bridge converters, Cuk converters, resonant converters, and linear regulators. The fly-back converter can more specifically be a quasi-resonant fly-back converter, or an active-clamp fly-back converter, or an interleaved fly-back converter, or a two-switch fly-back converter. Likewise, the forward converter can be more specifically a multi-resonant forward converter, or an active-clamp forward converter, or an interleaved forward converter, or a two-switch forward converter. And, the half-bridge converter can more specifically be an asymmetric half-bridge converter, or a multi-resonant half-bridge converter, or a LLC resonant half-bridge.

In the embodiment shown in FIG. 28, a source voltage 14 provides an input to a first switching network 12A, which is instantiated as a switching capacitor network. The output of the first switching network 12A is a lower voltage than the input voltage that is provided to a regulating circuit 16A (e.g. a buck, a boost, or a buck/boost converter). This regulating circuit 16A provides a regulated input voltage to a second switching network 12B, such as another switching capacitor network. A high voltage output of this second switching network 12B is then applied to a load 18A.

An embodiment such as that shown in FIG. 28 can be configured to regulate the load 18A or to regulate the voltage source 14 depending on the direction of energy flow.

In another embodiment, shown in FIG. 30, a low voltage source 14 connects to an input of a regulating circuit 16A, the output of which is provided to an input of a switching network 12A to be boosted to a higher DC value. The output of the switching network is then provided to a load 18A.

An embodiment such as that shown in FIG. 30 can be used to regulate the voltage source 14 or the load 18A depending on the direction of energy flow.

FIG. 31 shows the modular DC-DC converter 10C of FIG. 30, but with a controller 20A explicitly shown. The controller 20A is similar to that described in connection with FIG. 15.

As was discussed in connection with FIG. 15, the controller 20A features three sensor inputs, one for an intermediate voltage V_(X), one for the output voltage V_(O), and an optional one for the input voltage, V_(IN). The controller 20A also has two inputs that are not sensor inputs. One non-sensor input receives a clock signal CLK and the other receives a reference voltage V_(REF). The clock signal CLK is used to set the period of a second control signal PWM and the reference voltage V_(REF) is used to set the desired output voltage. Based on these inputs, the controller 20A outputs a first control signal having two phases to the switched-capacitor element 12A and a second control signal PWM to control switching of the regulating circuit 16A. This second control signal PWM is a pulse-width modulated signal.

Referring now to FIG. 32, another embodiment of a converter 100 includes a first regulating circuit 300A connected to a converter input 102 and a second regulating circuit 300B connected to a converter output 104. Between the first and second regulating circuits 300A, 300B is a switching network 200 having a switching network input 202 and a switching network output 204. The switching network 200 includes charge storage elements 210 interconnected by switches 212. These charge storage elements 210 are divided into first and second groups 206, 208.

In some embodiments, the switching network 200 is a bidirectional switching capacitor network such as that shown in FIG. 33.

The switching capacitor network in FIG. 33 features a first capacitor 20 and a second capacitor 22 in parallel. A first switch 24 selectively connects one of the first and second capacitors 20, 22 to a first regulating circuit 300A, and a second switch 26 selectively connects one of the first and second capacitors 20, 22 to the second regulating circuit 300B. Both the first and second switches 24, 26 can be operated at high frequency, thus facilitating the adiabatic charging and discharging of the first and second capacitors 20, 22.

The particular embodiment shown in FIG. 33 has a two-phase switching network 200. However, other types of switching networks can be used instead.

In yet another embodiment, shown in FIG. 34, multiple regulating circuits 16A, 16B, 16C are provided at an output of a first switching network 12A for driving multiple loads 18A-18C. For one of the loads 18C, a second switching network 12B is provided between the load 18C and the corresponding regulating circuit 16C thus creating a pathway similar to that shown in FIG. 30. FIG. 34 thus provides an example of how the modular construction of regulating circuits and switching networks facilitates the ability to mix and match components to provide flexibility in DC-DC converter construction.

A switched-capacitor power converter includes a network of switches and capacitors. By cycling the network through different topological states using these switches, one can transfer energy from an input to an output of the switched-capacitor network. Some converters, known as “charge pumps,” can be used to produce high voltages in flash and other reprogrammable memories.

To help understand the loss mechanisms in switched capacitor converters, it is instructive to first analyze the classical capacitor charging problem, as depicted in FIG. 35.

FIG. 35 shows a capacitor C initially charged to some value V_(C)(0). At t=0 the switch S is closed. At that instant, a brief surge of current flows as the capacitor C charges to its final value of V_(IN). The rate of charging can be described by a time constant τ=RC, which indicates the time it takes the voltage to either rise or fall to within 1/e of its final value. The instantaneous values for voltage across the capacitor v_(c)(t) and current through the capacitor i_(c)(t) are given by the following equations:

$\begin{matrix} {{{{v_{c}(t)} = {{v_{c}(0)} + {\left\lbrack {V_{in} - {v_{c}(0)}} \right\rbrack\left( {1 - e^{{{- t}/R}C}} \right)}}},{and}}{{i_{c}(t)} = {{{C\frac{dv_{c}}{dt}} = {\frac{V_{in} - {v_{c}(0)}}{R}e^{{{- t}/R}C}}}.}}} & \; \end{matrix}$

The energy loss incurred while charging the capacitor can be found by calculating the energy dissipated by resistor R, which is

E_(loss)(t) = ∫_(t = 0)^(∞)i_(R)(t) × v_(R)(t)  dt = ∫_(t = 0)^(∞)[i_(c)(t)]²R  dt.

The equation can be further simplified by substituting the expression for i_(c)(t) into the equation above. Evaluating the integral then yields

$\begin{matrix} {{E_{loss}(t)} = {{\frac{1}{2}\left\lbrack {V_{in} - {v_{c}(0)}} \right\rbrack}{{{\,^{2}C}\left\lbrack {1 - e^{{- 2}{t/R}c}} \right\rbrack}.}}} & \; \end{matrix}$

It is apparent therefore that the only term that involves the resistance is in a decaying exponential. Thus, if the transients are allowed to settle (i.e. t→∞), the total energy loss incurred in charging the capacitor is independent of its resistance R. In that case, the amount of energy loss is equal to

${{E_{loss}(\infty)} = {\frac{1}{2}C\Delta v_{c}^{2}}}.$

A switched-capacitor converter can be modeled as an ideal transformer, as shown in FIG. 36, with a finite output resistance R_(o) that accounts for the power loss incurred in charging or discharging of the energy transfer capacitors, as shown in FIG. 36. The embodiment shown in FIG. 36 is non-isolated because the negative terminals on both sides of the transformer are connected. However, this is by no means required. As an example, FIG. 37 shows an embodiment in which the same terminals are not connected, in which case the converter is isolated.

It should be noted that the transformer shown is only for modeling purpose. A converter of this type would generally not have windings wrapped around an iron core. The power losses associated with charging and discharging are typically dissipated in the ON resistance of the MOSFETs and equivalent series resistance of the capacitors.

The output voltage of the switched-capacitor converter is given by

${V_{o} = {{V_{in}\frac{N_{2}}{N_{1}}} - {I_{o}R_{o}}}}.$

There are two limiting cases where the operation of switched capacitor converters can be simplified and R_(o) easily found. These are referred to as the “slow-switching limit” and the “fast-switching limit.”

In the fast-switching limit (τ>>T_(sw)), the charging and discharging currents are approximately constant, resulting in a triangular AC ripple on the capacitors. Hence, R_(o) is sensitive to the series resistance of the MOSFETs and capacitors, but is not a function of the operating frequency. In this case, R_(o) of the converter operating in the fast-switching limit is a function of parasitic resistance and R_(o) is given by:

${R_{o}}_{\tau ⪢ T_{m}} = {R_{FSL} = {n{\sum\limits_{i \in {sw}}{\sum\limits_{j = 1}^{n}{{R_{i}\left( a_{r,i}^{j} \right)}^{2}.}}}}}$

Although it tends to under-estimate R_(o), a useful approximation for R_(o) that serves as a good starting point in the design process is given by

${{R_{o}(f)} \approx \sqrt{R_{FSL}^{2} + R_{SSL}^{2}}}.$

In the slow-switching limit, the switching period T_(sw) is much longer than the RC time constant τ of the energy transfer capacitors. Under this condition, a systemic energy loss given by ½C×ΔV_(c) ² occurs regardless of the resistances of the capacitors and switches. This systemic energy loss arises in part because the root mean square (RMS) of the charging and discharging current is a function of the RC time constant. Under these circumstances, R_(o) is given by

${R_{o}}_{\tau ⪡ T_{sw}} = {R_{SSL} = {\sum\limits_{i \in {caps}}{\sum\limits_{j = 1}^{n}{\frac{\left( a_{c,i}^{j} \right)^{2}}{2C_{i}f_{sw}}.}}}}$

The behavior of output resistance as a function of frequency can be appreciated by inspection of FIG. 38, which shows that as frequency increases, the output resistance drops in a manner consistent with the 1/f_(sw) term and that at higher frequencies, the output resistance settles down to a steady value.

The calculations for R_(SSL) and R_(FSL) given above are based on the charge multiplier vector concept. The vector a¹ through a^(n) can be obtained by inspection for any standard well posed n-phase converter. The charge multiplier vectors are computed using constraints imposed by Kirchoff's current law in each topological state along with the steady-state constraint that the n charge multiplier quantities must sum to zero on each capacitor.

Once R_(o) is known, the conduction loss P_(cond) can be calculated by

P_(cond) = I_(o)²R_(o).

Additionally, other losses such as switching losses, driver losses, and control losses can be calculated. Preferably, the switching loss is comparable to conduction loss. These losses, which originate from charging and discharging the transistor nodes, are given by

P_(sw) = W_(sw)f_(sw) = (W_(ds) + W_(on) + W_(g))f_(sw)

where W_(g) is the gate capacitance loss, W_(on) is the overlap or commutation loss, and W_(ds) is the output capacitance loss. Thus, the total converter loss can be calculated using

P_(loss) = I_(o)²R_(o) + W_(sw)f_(sw) + P_(etc).

Once R_(o) and the additional loss mechanisms have been determined, the total efficiency of the converter is given by

${\eta_{sc} = {\frac{P_{o}}{P_{o} + P_{loss}} = \frac{P_{o}}{P_{o} + P_{cond} + P_{sw} + P_{etc}}}}.$

To optimize efficiency of the switched-capacitor converter, the optimal switching frequency, capacitance, and device sizes must be selected. If the switching frequency is too low, then the conduction losses, P_(cond), dominate. On the other hand, if the switching frequency is too high, then P_(sw) dominates. Although doing so tends to decrease output ripple, rarely will a switched-capacitor converter operate far above the transitional region between the slow switching limit and fast switching limit. After all, operating above this region tends to increase switching losses without lowering the output resistance to compensate for those increases switching losses. Thus, there is little to gain by operating above that region.

If the effective resistance R_(eff) of the charging path is reduced, for example by reducing the RC time constant, the RMS current increases and it so happens that the total charging energy loss (E_(loss)=I_(RMS) ²R_(eff)=½C×ΔV_(C2)) is independent of R_(eff). One solution to minimize this energy loss is to increase the size of the pump capacitors in the switched capacitor network.

Although many switched-capacitor networks can provide a specific voltage transformation, most of them are impractical for a variety of reasons. A practical switched-capacitor network typically has a large transformation ratio, low switch stress, low DC capacitor voltage, and low output resistance. Suitable topologies for the converters described herein include Ladder, Dickson, Series-Parallel, Fibonacci, and Doubler topologies.

One useful converter is a series-parallel switched capacitor converter. FIGS. 39-40 show a 2:1 series-parallel switched-capacitor converter operating in charge phase and in discharge phase respectively. During the charge phase, the capacitors are in series. In the discharge phase, the capacitors are in parallel. In its charge phase the capacitor voltages v_(C1) and v_(C2) add up to V₁ while in its discharge phase v_(C1) and v_(C2) equal V₂. This means that V₂=V₁/2.

Another useful topology is that shown in FIGS. 41 and 42. In both charge pumps, the source is located at V₁ and the load is located at V₂. In these types of charge pumps, packets of charge are pumped along a diode chain as the coupling capacitors are successively charged and discharged. As shown in FIG. 43, clock signals v_(clk) and v_(clk) with amplitude v_(pump) are 180 degrees out of phase. The coupling capacitors can either be pumped in series or parallel.

It takes n clock cycles for the initial charge to reach the output. The charge on the final pump capacitor is n times larger than the charge on the initial pump capacitor. Thus, V₂ for the converters in FIG. 42 is V₁+(n−1)×v_(pump) in both pumping configurations.

Although the foregoing topologies are suitable for stepping up voltage, they can also be used to step down voltage by switching the location of the source and the load. In such cases, the diodes can be replaced with controlled switches such as MOSFETs and BJTs.

FIGS. 41 and 42 show topologies that transfer charge during only one phase of the clock signal. Such topologies are referred to as “half-wave” topologies because charge transfer only occurs during half of a clock cycle. A disadvantage of a half-wave topology is a discontinuous input current.

It is possible to convert the topologies shown in FIGS. 41 and 42 so that they transfer charge during both phases of the clock signal. This can be carried out by connecting two such topologies in parallel and driving them 180 degrees out of phase. Such a topology is referred to herein as a “full-wave” topology because charge transfer occurs in both halves of the clock cycle.

FIG. 44 show a topology derived from that shown in FIG. 41, but modified so that charge transfer occurs in both phases of the clock signal. FIG. 45 show a topology derived from that shown in FIG. 42, but modified so that charge transfer occurs in both phases of the clock signals. Instead of diodes, as shown in the topologies of FIGS. 41 and 42, the topologies shown in FIGS. 44 and 45 use switches. Unlike diodes, which are inherently unidirectional, the switches shown in FIG. 44 and FIG. 45 are bidirectional. As a result, in the topologies shown in FIGS. 44 and 45, power can flow either from the V₁ terminal to the V₂ terminal or vice versa. As such, these topologies can be used to step-up a voltage or step-down a voltage.

In the topologies shown thus far, there are two chains of switches, each of which is pumped. However, it is also possible to pump only one of the two switch chains. Such topologies are referred to as “asymmetric.”

In asymmetric topologies, half of the capacitors are used to support a DC voltage and not to transfer energy. However, these embodiments do not require that each switch endure such a high peak voltage. In particular, the peak voltage in the case in which only one switch chain is being pumped is only half of what it would be if both switch chains were actually being pumped. In these asymmetric topologies, the sole switch chain that is being used to transfer energy can be modified to transfer charge during both phases of the clock signal using principles set forth in connection with FIG. 44.

FIG. 46 shows eight exemplary topologies that use the principles set forth in connection with FIGS. 41-45. The first and second columns show half-wave topologies in both asymmetric and symmetric configurations, whereas the third and fourth columns show full-wave wave topologies in both asymmetric and symmetric configurations. The topologies shown in FIG. 46 can be further modified to combine N phases in parallel and to run them 180 degrees/N out of phase. Doing so reduces output voltage ripple and increases output power handling capability.

The basic building blocks in the modular architecture shown FIGS. 28, 29, 30, and 32 can either be connected as independent entities or coupled entities. In the situation where switching networks and regulating circuits are tightly coupled, it is possible to prevent and/or reduce the systemic energy loss mechanism of the switching networks through adiabatic charging. This generally includes using a regulating circuit to control the charging and discharging of the capacitors in the switching network. Furthermore, the output voltage of the regulating circuit and thus the total converter can be regulated in response to external stimuli. One approach to regulating the output voltage is by controlling the average DC current in the magnetic storage element.

In general, it is desirable for the regulating circuit to operate in a way that limits the root mean square (RMS) current through the capacitors in the switching network. The regulating circuit can do so using either resistive elements or magnetic storage elements. Because resistive elements consume power, magnetic storage elements are generally preferable for this purpose. Therefore, embodiments described herein rely on a combination of switches and a magnetic storage element in the regulating circuit to limit RMS current in the switching network.

To limit RMS current, the regulating circuit forces the capacitor current through the magnetic storage element in a regulating circuit that has an average DC current. The switches in the regulating circuit then operate to maintain an average DC current through the magnetic storage element.

The regulating circuit may limit both the RMS charging current and the RMS discharging current of at least one capacitor in the switching network. A single regulating circuit may limit the current into or out of the switching network by sinking and/or sourcing current. Therefore, there are four fundamental configurations, which are shown in FIGS. 28, 29, 30, and 32.

Assuming power flows from source to load then, in FIG. 28, the regulating circuit 16A may sink both the charging and discharging current of the switching network 12A.

In FIG. 29, the regulating circuit 16A may source both the charging and discharging current of the switching network 12B while also sinking both the charging and discharging current of the switching network 12A. Furthermore, if both the switching networks and the regulating circuits allow power to flow in both directions, then bidirectional power flow is possible.

In FIG. 30, the regulating circuit 16A may source both the charging and discharging current of the switching network 12A.

In FIG. 32, the regulating circuit 300A may source the charging current of switching network 200 and the regulating circuit 300B may sink the discharging current of the same switching network 200 and vice-versa.

A fundamental difficulty that afflicts switched-capacitor networks is that the mere act of charging a capacitor incurs energy loss. This energy loss depends a great deal on how much the voltage across the capacitor changes as a result of the charging event. The energy loss E_(L) associated with using a fixed voltage source at a voltage V to charge a capacitance C from zero to Vis ½CV². This loss does not depend on the parasitic series resistance R. Since this loss arises whenever voltage changes, every charging interval during operation incurs a loss equal to ½CΔV², where ΔV corresponds to the difference between the initial and final value of the capacitor voltage.

The fixed charge-up loss cannot be reduced by employing switches with lower on-state resistance. Known ways to reduce it simply avoid causing the voltage to change very much during operation. This is why such converters operate most efficiently only at certain conversion ratios.

Since the amount of charge transferred into or out of a charging cycle is the product of the voltage difference and the capacitance, one way to transfer a great deal of charge with only a small voltage difference is to make the capacitance very large. However, large capacitors are not without disadvantages. For one thing, a large capacitance consumes a great deal of physical area. Additionally, switched-capacitor networks with large capacitances are not so amenable to efficient operation.

A converter as described herein overcomes the foregoing disadvantage by providing more efficient use of the capacitors. This means that capacitors can be made smaller and/or that there will be an overall improvement in system efficiency. Although a converter as described herein does not require a reconfigurable switched-capacitor circuit, it may nevertheless take advantage of one as described above.

FIG. 47 illustrates a method for improving the charge-up efficiency of the capacitor C shown in FIG. 35 after switch S closes. The regulating circuit 16A adiabatically charges the capacitor C. In some embodiments, the regulating circuit 16A is a switch-mode converter that supplies an output. A suitable regulating circuit is a low-voltage magnetic based converter.

In the system shown in FIG. 47, while the capacitor C charges, most of the difference between the input voltage V_(IN) and the capacitor stack voltage V_(C) appears across the input of the regulating circuit 16A. Instead of being dissipated as heat in a parasitic resistor R, the energy associated with charging the capacitor stack is delivered to the output of the regulating circuit 16A instead. Therefore, a majority of the capacitor-charging energy can be recovered (i.e., redirected to the load) by making the apparent input resistance of the regulating circuit 16A higher than the parasitic resistor R.

The embodiment shown in FIG. 47 thus permits more efficient use of capacitors than that shown in FIG. 35. This enables reduction in the required capacitor size and/or improvement in system efficiency when extended to switched-capacitor converters.

FIG. 48 illustrates one implementation of the foregoing embodiment in which a switching network 12A connects to regulating circuit 16A that serves as both a means to adiabatically charge/discharge the capacitors in the switching network 12A and regulate the output voltage V_(O). Please note, the regulating circuit 16A need not be at a higher frequency than the switching network to promote adiabatic operation; it can even be at a lower frequency. In the particular embodiment shown, the regulating circuit 16A is a synchronous buck converter and the switching network 12A is a single-phase series-parallel converter. The switching network 12A features first switches 1 that open and close together, second switches 2 that also open and close together, a first pump capacitor C₁, and a second pump capacitor C₂.

The regulating circuit 16A includes a filter capacitor C_(X) that serves only as a filter and bypass for the regulating circuit 16A. Consequently, the capacitance of the filter capacitor C_(X) should be much smaller than that of the first and second pump capacitors C₁ and C₂ of the switching network 12A.

The switching network 12A alternates between being in a charging state and a discharging state. During the charging state, it charges the first and second pump capacitors C₁, C₂. Then, during the discharging state, it discharges the first and second pump capacitors C₁, C₂ in parallel.

In the charging state, the first switches 1 close and the second switches 2 open. The difference between the input voltage V_(IN), and the sum of the voltages across the first and second pump capacitors C₁, C₂ appears across the input terminal of the regulating circuit 16A. As a result, the first and second pump capacitors C₁, C₂ charge with low loss, and at a rate determined by the power drawn from the regulating circuit 16A to control the system output.

Similarly, in the discharging state, the second switches 2 close and the first switches 1 open. The switching network 12A then discharge in parallel at a rate based on the power needed to regulate the output.

Another embodiment relies on at least partially adiabatically charging full-wave cascade multipliers. Cascade multipliers are a preferred switching network because of their superior fast-switching limit impedance, ease of scaling up in voltage, their two-phase operation, and low switch stress.

In cascade multipliers, the coupling capacitors are typically pumped with a clocked voltage source v_(clk) & v_(clk) . However, if the coupling capacitors are pumped with a clocked current source i_(clk) & i_(clk) instead, as shown in FIG. 49, then the RMS charging and discharging current in the coupling capacitor may be limited. In this case, the capacitors are at least partially charged adiabatically thus lowering, if not eliminating, the ½C ΔV_(c) ² loss that is associated with a switched-capacitor converter when operated in the slow-switching limit. This has the effect of lowering the output impedance to the fast-switching limit impedance. As shown by the black dotted line in FIG. 50, which depicts adiabatic operation under full adiabatic charging, the output impedance would no longer be a function of switching frequency.

With all else being equal, an adiabatically charged switched-capacitor converter can operate at a much lower switching frequency than a conventionally charged switched-capacitor converter, but at higher efficiency. Conversely, an adiabatically charged switched-capacitor converter can operate at the same frequency and with the same efficiency as a conventionally charged switched-capacitor converter, but with much smaller coupling capacitors, for example between four and ten times smaller.

Embodiments described herein can operate with two clocked current sources i_(clk), i_(clk) that operate 180 degrees out of phase, as shown in FIG. 51. One implementation, shown in FIG. 52, uses one current source 72, a first switch pair 1 and a second switch pair 2. The first and second switch pairs 1, 2 are best synchronized with a switch chain. A suitable implementation of the current source in FIG. 52 is an inductance, represented in FIG. 53 by an inductor L.

FIG. 54 shows the cascade multiplier of FIG. 49 with the clocked current sources in FIG. 52. FIG. 55 shows the cascade multiplier of FIG. 49 with the clocked current sources in FIG. 53. There are numerous ways of implementing the current source 72. These include buck converters, boost converters, fly-back converter, resonant converters, and linear regulators. In some embodiments, a power converter having a constant input current implements the constant current source. In other embodiments, a power converter that has a constant input current for a portion of an interval defined by the reciprocal of its switching frequency implements the constant current source. In yet other embodiments, a linear regulator implements the constant current source.

In the embodiment shown in FIG. 55, the inductor L should limit the RMS current through the coupling capacitors (to provide adiabatic operation) while also providing a relatively constant output voltage V_(O). This can be achieved by having a large inductance and/or a capacitance (not shown) in parallel with the load 18A. However, a large inductance consumes considerable area. And to make matters worse, the windings necessary for a large inductance will cause considerable resistive losses.

By correctly choosing the inductance and capacitance (not shown) in FIG. 55, it is possible to constrain the current I_(X) while generating a relatively static output voltage V_(O). In particular, a proper choice of inductance will generate a rectified sinusoidal current I_(X) as shown in FIG. 56 that will nevertheless result in a limited RMS current through the coupling capacitors and a relatively constant output voltage V_(O).

In FIG. 56, the boundary between each half-cycle of the sinusoid corresponding to a switching event of the switches of the clocked current source. Ideally, the current I_(X) should be zero whenever a switching event occurs. This will minimize switching losses. However, in practice it is difficult to achieve such precision. Moreover, in any attempt to achieve such precision, there is a risk that the inductance is smaller than what was expected. This will cause the current I_(X) to become negative, thus potentially destabilizing the circuit.

Accordingly, when choosing the inductance of L in FIG. 55, it is desirable to choose an inductance that is small enough to avoid consuming excessive area and generating loss, but that is large enough to provide some assurance that the current I_(X) will just graze the zero line without actually becoming negative. A suitable value of inductance can be obtained by dividing the peak-to-peak value of the voltage V_(X) by the product of the average value of the current I_(X) and the switching frequency. The result is then multiplied by a constant. A suitable constant is 13/24.

FIG. 57 shows a step-down converter consistent with the architecture shown in FIG. 28. However, in this embodiment, a switching network 12A is adiabatically charged using a regulating circuit 16A. The clocked current sources i_(clk) & i_(clk) are emulated by Four switches and the regulating circuit 16A emulate the clocked current sources i_(clk), i_(clk) . The output capacitor C_(O) has also been removed so as to allow V_(X) to swing. In this example, the regulating circuit 16A is a boost converter that behaves as constant source with a small AC ripple. Any power converter that has a non-capacitive input impedance at the frequency of operation would have allowed adiabatic operation. Although switch-mode power converters are attractive candidates due to their high efficiency, linear regulators are also practical.

In operation, closing switches labeled “1” charges capacitors C₄, C₅, and C₆ while discharging capacitors C₁, C₂, and C₃. Similarly, closing switches “2” has the complementary effect. The first topological state (phase A) is shown in FIG. 57, where all switches labeled “1” are closed and all switches labeled “2” are opened. Similarly, the second topological state (phase B) is shown in FIG. 58, where all switches labeled “2” are closed and all switches labeled “1” are opened.

In this embodiment, the regulating circuit 16A limits the RMS charge and discharging current of each capacitor. For example, capacitor C₃ is discharged through the filter inductor in the regulating circuit 16A during phase A, while capacitor C₃ is charged through the filter inductor in regulating circuit 16A during phase B, clearly demonstrating the adiabatic concept. Furthermore, all of the active components are implemented with switches so that the converter can process power in both directions.

A few representative node voltages and currents are shown in FIG. 60. There is a slight amount of distortion on the rising and falling edges of the two illustrated currents (I_(P1) and I_(P2)), but for the most part, the currents resemble two clocks 180 degrees out of phase. In general, adiabatic charging occurs in cascade multipliers if at least one end of a switch stack is not loaded with a large capacitance, as is the case in this embodiment, where the V_(X) node is loaded down by regulating circuit 16A.

In operation, different amounts of current will flow through different switches. It is therefore useful to size the switches in a manner appropriate to the currents that will be flowing through them. For example, the switches connected to V_(P1) and V_(P2) carry more current then the other switches in FIG. 57. By making these switches larger than the other switches, this avoids the need to have unnecessarily large switches and thus results in a smaller circuit footprint. This also avoids unnecessary additional capacitive losses, which are proportional to the size of the switch.

The switches shown in FIG. 57 will transition between states at some switching frequency. It is desirable that, in order to reduce loss, the switching network 12A operate such that the RMS current through the switches is constrained at that switching frequency. One way to ensure that this is the case is to choose the resistances of the switches such that they are so large that the RC time constant of the charge transfer between the capacitors is similar if not longer than the switching frequency. As can be seen in FIG. 50, by controlling the width “W” of the switches and hence their resistance and their size, the switching network 12A can be forced into the fast-switching limit region.

Unfortunately, by using the resistance of the switches to constrain the RMS current, conductive power losses increase and the overall efficiency decreases. The regulating circuit 16A, however, allows us to reduce the resistance of the switches and operate adiabatically. Therefore, the switches can be optimally sized for the highest efficiency without worrying about constraining the RMS current since it is handled by the regulating circuit 16A (or optionally a magnetic filter). The optimal size for each switch is chosen by balancing the resistive and capacitive losses in each switch at a given switching frequency and at a given current.

The modular architecture with the basic building blocks shown in FIGS. 11, 29, 30, and 32 may be expanded to cover a wider range of applications, such as high-voltage DC, AC-DC, AC-AC, buck-boost, and multiple output voltages. Each of these applications includes separating the transformation and regulation functions. Extension of the architecture can also incorporate adiabatically charged switched-capacitor converters.

In many switched-capacitor converters, the number of capacitors and switches increases linearly with the transformation ratio. Thus, a large number of capacitors and switches are required if the transformation ratio is large. Alternatively, a large transformation ratio can be achieved by connecting numerous low gain stages in series, either without intervening filters, as depicted in FIG. 61, or with intervening filters between stages, as shown in FIG. 63. The transformation ratio of the total switch capacitor stack (V_(IN)/V_(X)) is as follows:

$\begin{matrix} {\frac{V_{in}}{V_{x}} = {N_{1} \times N_{2}\mspace{14mu}\ldots\mspace{14mu} N_{n}}} & (2.1) \end{matrix}$

The main disadvantage of the series stacked configuration is that the voltage stresses on the front stages are much higher than those of the rear stages. This will normally require stages with different voltage ratings and sizes. However, the transformation ratio can be easily changed by bypassing a stage or two.

Adiabatic charging of a preceding series-connected switching network only occurs if the following switching network controls the charging and discharging current of the preceding stage. Thus, it is preferable to use full-wave switched-capacitor converters in the front stages or to use switched-capacitor stages such as the single-phase series-parallel switched-capacitor converters with magnetic based filters.

FIG. 62 shows a converter with two series-connected switching networks consistent with the architecture shown in FIG. 61. FIG. 64 shows a similar architecture, but with filters between the series-connected switching networks in a manner consistent with the architecture shown in FIG. 63. Both switching networks 12A, 12D are two-phase cascade multipliers. In operation, switches labeled “1” and “2” are always in complementary states and switches labeled “7” and “8” are always in complementary states. Thus, in a first switched-state, all switches labeled “1” are open and all switches labeled “2” are closed. In a second switched-state, all switches labeled “1” are closed and all switches labeled “2” are opened. In this embodiment, closing switches 1 charges capacitors C₁, C₂, C₃, while discharging capacitors C₄, C₅, C₆ and closing switches 2 has the complementary effect. Also, closing switches 7 charges capacitors C₇, C₈, C₉, while discharging capacitors C₁₀, C₁₁, C₁₂ and closing switches 8 has the complementary effect.

The power converter provides a total step-down of 32:1, assuming the regulating circuit 16A is a buck converter with a nominal step-down ratio of 2:1. Furthermore, if the input voltage is 32 V and the output voltage is 1 V, then the switches in the first switching network 12A will need to block 8 volts while the switches in the second switching network 12D will need to block 2 volts.

The modular architecture with the basic building blocks shown in FIGS. 11, 29, 30, and 32 may be configured to handle an AC input voltage as shown in FIG. 65. An AC rectification stage 19A receives an AC waveform from an AC source 14B and provides an average DC voltage to a converter 10, the output of which is connected to a load 18A. In this embodiment, the converter 10 can be isolated or otherwise.

One of the main attributes of switched-capacitor converters is their ability to operate efficiency over a large input range by reconfiguring the switched-capacitor network. If the AC wall voltage (i.e. 60 Hz & 120 V_(RMS)) can be thought of as a slow-moving DC voltage, then a front-end AC switching network 13A should be able to unfold the time-varying input voltage into a relatively stable DC voltage.

FIG. 66 shows a diagram of a 120 V_(RMS) AC waveform over a single 60 Hz cycle overlaid with the unfolded DC voltage. FIG. 67 shows an AC switching network 13A of the sort that can incorporate the AC rectification stage 19A of FIG. 65. The AC switching network 13A is a front-end switched-capacitor stage (i.e., switching network) in combination with a selective inverting stage (i.e., rectifying stage). The front-end switched-capacitor stage has different configurations (1/3, 1/2, 1/1) at its disposal. In the particular embodiments shown, the AC switching network 13A keeps the DC voltage under 60 V. In some embodiments, the AC switching network 13A is a special-purpose adiabatic switched-capacitor network.

Once the AC switching network 13A has unfolded the AC voltage, a regulating circuit 16A, shown in FIG. 67, produces a final output voltage. In some embodiments, another switching network 16A between the AC switching network 13A and the regulating circuit 16A further conditions the voltage. If this is the case, then the caveats for series-connected stages hold true since the AC switching network 13A is a special purpose switching network 12A. Some form of magnetic or electric isolation is also common in AC-DC converters for safety reasons. Hence, in FIG. 67, voltages: V_(AC), V_(DC), and V_(O) are purposely defined as being agnostic to a common ground.

FIG. 68 shows an AC-DC converter corresponding to the architecture shown in FIG. 67. In this embodiment, the AC switching network 13A is a synchronous AC bridge rectifier followed by a reconfigurable two-phase step-down cascade multiplier with three distinct conversion ratios (1/3, 1/2, 1/1) while the regulating circuit 16A is a synchronous buck converter. In operation, switches labeled 7 and 8 are always in complementary states. During the positive portion of the AC cycle (0 to π radians) all switches labeled “7” are closed while all switches labeled “8” are opened as shown in FIG. 69. Similarly, during the negative portion of the AC cycle (π to 2π radians) all switches labeled 8 are closed while all switches labeled “7” are opened as shown in FIG. 70.

In addition to the inverting function provided by switches 7 and 8, switches 1A-1E and switches 2A-2E may be selectively opened and closed as shown in Table 1 to provide three distinct conversion ratios of: 1/3, 1/2, and 1.

TABLE 1 V₂/V₁ 1A 1B 1C 1D 1E 2A 2B 2C 2D 2E 1/3 CLK CLK CLK CLK CLK CLKB CLKB CLKB CLKB CLKB 1/2 CLKB CLK CLK CLK CLK CLK CLKB CLKB CLKB CLKB 1/1 ON ON ON OFF OFF ON ON ON OFF OFF

The AC switching network 13A is provided with a digital clock signal CLK. A second signal CLKB is also generated, which may simply be the complement of CLK (i.e. is high when CLK is low and low when CLK is high), or which may be generated as a non-overlapping complement. With a switching pattern set in accordance with the first row of Table 1, the AC switching network 13A provides a step-down ratio of one-third (⅓). With a switching pattern set in accordance with the second row of Table 1, the AC switching network 13A provides a step-down ratio of one-half (½). With a switching pattern set in accordance with the third row of Table 1, the AC switching network 13A provides a step-down ratio of one.

Most power supplies attached to the wall meet some power factor specification. Power factor is a dimensionless number between 0 and 1 that defines a ratio of the real power flowing to apparent power. A common way to control the harmonic current and thus boost the power factor is by using an active power factor corrector. FIG. 71 shows an AC-DC converter 8 that controls harmonic current and boosts power factor towards unity. The illustrated AC-DC converter 8 features an AC switching network 13A that receives an AC voltage from an AC source 14B and rectifies it. An output of the AC switching network 13A connects to an input of an active power-factor correction circuit 17A. The AC switching network 13A may also provide voltage transformation via a switched-capacitor circuit. The power-factor correction circuit 21A controls its input current so that it remains, to the greatest extent possible, in-phase with the voltage waveform provided by the AC source 14B. This drives reactive power toward zero. The output of the power-factor correction circuit 17A is then provided to a regulating circuit 16A that operates in the same way as shown in FIG. 67.

FIG. 72 shows a particular embodiment of FIG. 65's modular power converter 10 connected between first and second circuits 51, 52. The first and second circuits 51, 52 can be a source, a load, or another circuit, such as a power converter, a PFC circuit, or an EMI filter.

The illustrated power converter 10 includes a regulating circuit 16A, a switching network 12A, and an isolated controller 60. As used herein, a circuit having an input and an output is considered isolated if the input voltage and the output voltage do not share a common ground. Such isolation can be carried out by having the input voltage correspond to an input voltage of a transformer and having the output voltage corresponds to an output voltage of a transformer. In some embodiments, the regulating circuit 16A is isolated. In other embodiments, it is the switching network 12A that is isolated. Although only one of the foregoing is needed to consider the modular DC-DC converter 10 as a whole isolated, there are also embodiments in which both the switching network 12A and the regulating circuit 16A are isolated.

In some embodiments, the switching network 12A is an unregulated switched-capacitor converter having a fixed voltage-conversion ratio. These embodiments generally include a regulating circuit 16A to regulate the output of the switching network 12A. Examples of a suitable regulating circuit 16A include a boost converter, a buck converter, a fly-back converter, and a linear regulator.

FIG. 73 shows a variation of the converter shown in FIG. 72 in which an LC filter 21A is added between the switching network 12A and the second circuit 252. The purpose of the LC filter is to promote adiabatic charging of the switching network 12A via the method shown in FIG. 53.

FIG. 74 shows a particular embodiment of the modular DC-DC converter 10 shown in FIG. 73. The regulating circuit 16A is implemented as a fly-back converter having a switch S₁, a diode D₁, a capacitor C₁, and a transformer T₁. When operating in continuous conduction mode, the regulating circuit 16A transitions between first and second states. In the first state, the switch S₁ is closed, and the diode D₁ does not conduct. During this first state, the capacitor C₁ acts as a charge reservoir to supply power to the output of the regulator 16A. In the second state, the switch S₁ is opened and the diode D₁ conducts.

As shown in FIG. 74, the isolated controller 60 includes a first control signal CTR1 that controls the switching network 12A, a second control signal CTR2 that controls the regulating circuit 16A, and an isolation barrier 61 between them. As a result, the first and second control signals CRT1, CTR2 have different grounds and connect to different sides of the transformer T₁. The isolation barrier 61 can include any one or more of sonic isolation, optical isolation, capacitive isolation, inductive isolation, and mechanical isolation.

The embodiment shown in FIG. 29 can be modified to operate with an AC source 14B, as shown in FIG. 75, which shows a modular DC-DC converter 10 connected between first and second circuits 51, 52. The modular DC-DC converter 10 includes first and second switching networks 12A, 12B and a regulating circuit 16A. The first switching network 12A receives, at its input thereof, a voltage from the first circuit 251. The second switching network 12B provides its output to the second circuit 252. The regulating circuit 16A receives an output from the first switching network 12A and provides its own output to an input of the second switching network 12B. An isolated controller 60 provides a first control signal to the first switching network 12A, a second control signal to the second switching network 12B, and a third control signal to the regulating circuit 16A.

Similarly, the embodiment shown in FIG. 32 can be modified to operate with an AC source 14B, as shown in FIG. 76, which shows first and second regulating circuits 16A, 16B and a switching network 12A. The first regulating circuit 16A receives, at its input, a voltage from the first circuit 251. The second regulating circuit 16B provides its output to the second circuit 252. The switching network 12A receives an output from the first regulating circuit 16A and provides its own output to an input of the second regulating circuit 126. An isolated controller 60 provides a first control signal to the first regulating circuit 16A, a second control signal to the regulating circuit 16B, and a third control signal to the switching network 12A. In some embodiments, as shown in FIG. 73, the second regulating circuit 16B can be implemented as an LC filter 21A. The AC rectification stage 19A shown in FIG. 65 can be implemented in a variety of ways. In one embodiment, shown in FIG. 77, the rectifier 19A features a fuse 71, a capacitor C₁, an AC bridge 80, and a first electromagnetic interference filter 70A between the AC bridge 80 and the AC source 14B. In another embodiment, shown in FIG. 78, a second EMI filter 70B and a power-factor correction circuit 90 replaces the capacitor C₁.

The first electromagnetic interference filter 70A, implementations of which can be seen in FIGS. 79 and 80, reduces the common-mode and differential-mode noise produced by the AC-DC converter 8 by a desired amount. The extent to which such noise is reduced is typically set by a government body, such as the FCC.

The AC bridge 80 accepts an AC voltage and outputs an average DC voltage. A particular implementation of an AC bridge 80 is shown in FIG. 81. The bridge includes first, second, third, and fourth diodes D₁, D₂, D₃, D₄. In operation, the AC bridge 80 transitions between first and second states. In the first state, the first and third diodes D₁, D₃ are reverse biased, and the second and fourth diodes are forward biased. In the second state, the second and fourth diodes D₂, D₄ are forward biased and the first and third diodes D₁, D₃ are reverse biased.

Many modern devices require different voltages to operate different components, such as power management integrated circuits (PMICs) in cell phones. For example, one voltage may be required to operate a processor, whereas another voltage may be needed to operate a display. In principle, one could have a separate transformation stage and regulation stage corresponding to each required output voltage. However, this solution is wasteful both of physical space and of pin count. A solution to this difficulty is that shown in FIG. 82, in which one transformation stage drives two or more regulation stages in parallel. Each regulation stage thus provides a separate output voltage. The regulator stage can be any of those already described, including a linear regulator. As shown in FIG. 83, some embodiments include a filter between the transformation stage and the regulation stages.

To ensure adiabatic charging of the switched-capacitor network in the transformation stage, it is preferable that the majority of the power drawn by the various regulation stages come by way of a constant current (or constrained current). This can be achieved, for example, by synchronizing the regulation stages so that they draw as constant a current as possible, thus avoiding larger resistive losses (i.e., due to higher RMS current) in the switched-capacitor network of the transformation stage.

FIGS. 84-80 show specific implementations of modular power converters that conform to the architectural diagrams shown in FIGS. 28, 29, 30, and 32. In each implementation a regulating circuit or multiple regulating circuits may limit both the RMS charging current and the RMS discharging current of at least one capacitor in each switching network so all of these switching networks are adiabatically charged switching networks. However, if decoupling capacitors 9A or 9B are present, then the ability of the regulating circuit to limit the RMS charging and discharging current may be diminished. Capacitors 9A and 9B are optional and to keep the output voltage fairly constant capacitor C_(O) is used. All of the stages share a common ground, however this need not be case. For example, if a regulating circuit is implemented as a fly-back converter than the ground can be separated easily, even a switching network can have separate grounds through capacitive isolation. Furthermore, for simplicity, the switching network in each implementation has a single conversion ratio. However, reconfigurable switching networks that provide power conversion at multiple distinct conversion ratios may be used instead.

In operation, switches labeled “1” and “2” are always in complementary states. Thus, in a first switched-state, all switches labeled “1” are open and all switches labeled “2” are closed. In a second switched-state, all switches labeled “1” are closed and all switches labeled “2” are opened. Similarly, switches labeled “3” are “4” are in complementary states, switches labeled “5” are “6” are in complementary states, and switches labeled “7” are “8” are in complementary states. Typically, the regulating circuits operate at higher switching frequencies than the switching networks. However, there is no requirement on the switching frequencies between and amongst the switching networks and regulating circuits.

FIG. 84 shows a step-up converter corresponding to the architecture shown in FIG. 11. In this embodiment, the switching network 12A is a two-phase step-up cascade multiplier with a conversion ratio of 1:3 while the regulating circuit 16A is a two-phase boost converter. In operation, closing switches labeled 1 and opening switches 2 charges capacitors C₃ and C₄ while discharging capacitors C₁ and C₂. Conversely, opening switches 1 and closing switches 2 charges capacitors C₁ and C₂ while discharging capacitors C₃ and C₄.

FIG. 8 shows bidirectional step-down converter corresponding to the architecture shown in FIG. 28. In this embodiment, the switching network 12A is a two-phase step-down cascade multiplier with a conversion ratio of 4:1 while the regulating circuit 16A is synchronous buck converter. In operation, closing switches 1 and opening switches 2 charges capacitors C₁, C₂, and C₃ while discharging capacitors C₄, C₅, and C₆. Conversely, opening switches 1 and closing switches 2 charges capacitors C₄, C₅, and C₆ while discharging capacitors C₁, C₂, and C₃. All of the active components are implemented with switches so that the converter can process power in both directions.

FIG. 86 shows a step-up converter consistent with the architecture shown in FIG. 30. In this embodiment, the regulating circuit 16A is boost converter while the switching network 12A is a two-phase step-up series-parallel switched-capacitor converter with a conversion ratio of 1:2. In operation, closing switches 1 charges capacitor C₂ while discharging capacitor C₁. Closing switches 2 has the complementary effect.

FIG. 87 shows a bidirectional up-down converter consistent with the architecture shown in FIG. 30. In this embodiment, the regulating circuit 16A is synchronous four switch buck-boost converter while the switching network 12A is a two-phase step-up cascade multiplier with a conversion ratio of 1:4. In operation, closing switches 1 charges capacitors C₄, C₅, and C₆ while discharging capacitors C₁, C₂, and C₃. Closing switches 2 has the complementary effect. All of the active components are implemented with switches so that the converter can process power in both directions.

FIG. 88 shows an inverting up-down converter consistent with the architecture shown in FIG. 2. In this embodiment, the first switching network 12A is a step-down series-parallel switched-capacitor converter with a conversion ratio of 2:1, the first regulating circuit 16A is a buck/boost converter; and the second switching network 12B is a step-up series-parallel switched-capacitor converter with a conversion ratio of 1:2. In operation, closing switches 1 charges capacitor C₁ while closing switches 2 discharges capacitor C₁. Similarly, closing switches 7 discharges capacitor C₂ while closing switches 8 charges capacitor C₂.

FIG. 89 shows a bidirectional inverting up-down converter consistent with the architecture shown in FIG. 29. In this embodiment, the first switching network 12A is a two-phase step-down series-parallel switched-capacitor converter with a conversion ratio of 2:1, the regulating circuit 16A is a synchronous buck/boost converter and the second switching network 12B is a two-phase step-up series-parallel switched-capacitor converter with a conversion ratio of 1:2. In operation, closing switches 1 charges capacitor C₁ while discharging capacitor C₂. Closing switches 2 has the complementary effect. Similarly, closing switches 7 charges capacitor C₄ while discharging capacitor C₃. Closing switches 2 has the complementary effect. All of the active components are implemented with switches so that the converter can process power in both directions.

FIG. 90 shows a step-down converter consistent with the block diagram shown in FIG. 32. In this embodiment, the first regulating circuit 300A is a boost converter, the switching network 200 is a two-phase step-up series-parallel switched-capacitor converter with a conversion ratio of 1:2, and the second regulating circuit 300B is a boost converter. In operation, closing switches 1 charges capacitors C₁ and C₂ while simultaneously discharging capacitors C₃ and C₄. Closing switches 2 has the complementary effect.

FIG. 80 shows a bidirectional up-down converter consistent with the block diagram shown in FIG. 32. In this embodiment, the first regulating circuit 300A is a synchronous boost converter, the switching network 200 is a two-phase fractional step-down series-parallel switched-capacitor converter with a conversion ratio of 3:2 and the second regulating circuit 300B is a synchronous buck converter. In operation, closing switches 1 charges capacitors C₃ and C₄ while simultaneously discharging capacitors C₁ and C₂. Closing switches 2 has the complementary effect. All of the active components are implemented with switches so that the converter can process power in both directions.

It should be understood that the topology of the regulating circuit can be any type of power converter with the ability to regulate the output voltage, including, but without limitation, synchronous buck, three-level synchronous buck, sepic, soft switched or resonant converters. Similarly, the switching networks can be realized with a variety of switched-capacitor topologies, depending on desired voltage transformation and permitted switch voltage.

The physical implementation of the foregoing switching networks 12A includes four primary components: passive device layers, active device layers, interconnect structures, and thru-vias. The passive device layers have passive devices, such as capacitors. The active device layers have active devices, such as switches.

The separation of active and passive devices in different layers arises because active devices are made by CMOS processing. Thus, if one has passive devices on the same layer, they must be made by CMOS-compatible processing steps to avoid destroying the active devices. This constraint makes it difficult to manufacture capacitors that provide high capacitance in a small area of the chip. It also makes it difficult to make high Q inductors. To avoid these difficulties, it is preferable to produce integrated passive devices on their own wafer with a process flow that is optimized for producing such passive devices.

In some embodiments, the devices are integrated into a single monolithic substrate. In other embodiments, the devices are integrated into multiple monolithic substrates. The monolithic substrates are typically made of semiconductor material, such as silicon.

In a preferred practice, one makes passive devices on a passive device layer using an integrated passive device process and makes active devices on an active device layer using a CMOS process. These device layers are electrically connected together through a fine interconnect structure that includes thru-vias to allow electrical connections across device layers.

FIG. 92 shows a circuit block diagram of a modular converter that uses capacitors in a switched-capacitor circuit to transfer energy. The block diagram shows a stack of layers that includes layers for both switches and capacitors. The switches within the stack of layers include first and second switches S₁, S₂. The capacitors within the stack of layers includes first and second capacitors C₁, C₂. A discrete inductor L₁ is mounted outside the layer stack.

The layers within the stack of layers in FIG. 92 can be stacked in different ways. FIGS. 93-95 show side views of different ways of stacking layers, and placement of the interconnect structure and vias corresponding to each such configuration of layers. The active device layers (also known as switch device layer) include switches while the passive device layers include capacitors.

In FIG. 93, an active device layer connects to a printed-circuit board via a set of C4 bumps and a passive device layer is stacked above the active device layer. Thru-vias TV provide a connection between the printed-circuit board and an interconnect structure between the two layers.

In FIG. 94, this orientation is reversed, with the passive layer being connected to the printed-circuit board by the C4 bumps and the active layer above the passive layer. Once again, thru-vias TV provide a connection between the printed-circuit board and an interconnect structure between the two layers.

FIG. 95 shows the possibility of stacking multiple passive or active layers. In the particular embodiment shown, there are n passive devices layers and one active device layer. Through vias TV provide a path for connecting the printed-circuit board to interconnect structures between adjacent layers.

FIG. 96 shows an embodiment that has at least two device layers, one of which has switches and another of which has capacitors.

The C4 bumps are laid out along the printed-circuit board at a first pitch. An interconnect structure includes C5 bumps laid out at a second pitch that is smaller than the first pitch. An example of such C5 bumps can be seen in FIG. 106.

Each passive layer has capacitors that occupy a certain footprint on the chip. The capacitors are located such that each one is within a footprint of a switch on an active layer that is above or below the passive layer. Such an arrangement helps reduce energy loss and other parasitic losses in the interconnect structures.

Additional permutations arise because, as a result of the nature of known semiconductor fabrication processes, it is common to process only one face of a wafer. This face of the wafer has devices integrated into it. For this reason, it is called the “device face.”

For each stack configuration, there are now additional permutations concerning whether the device face is an upper face or a lower face. For a given layer, with reference to the z-axis shown in FIGS. 93-95, an “upper face” of that layer faces in the +z direction a “lower face” faces in the −z direction.

As used herein, a layer is said to “face” the +z direction if a vector that is perpendicular to a plane defined by that layer and that is directed in a direction away from that layer is directed in the +z direction. A layer is said to face in the −z direction if it does not face the +z direction.

For the case in which there are only two device layers, FIGS. 97-99 show the four possible configurations of device faces when the upper layer is the passive layer, as shown in FIG. 93. FIGS. 101-104 show the four possible configurations of device faces when the upper layer is the active layer, as shown in FIG. 94.

In FIG. 97, the active layer's device face is its upper face and the passive layer's device face is its lower face. Given that there are only two layers, this means they face each other. FIG. 99 shows a converse case in which the passive layer's device face is its upper face and the active layer's device face is its lower face. In FIG. 98, both the device faces of both the active and passive layers are on upper faces, whereas in FIG. 100 both are on lower faces.

FIGS. 101-104 show the converse of FIGS. 97-100 for the case in which the active layer is now the upper layer. In FIG. 101, the active devices are on a lower face and the passive devices are on an upper face. Since there are only two layers, the active and passive devices face each other as they did in FIG. 97. In FIG. 102, the active devices and passive devices are on upper faces of their respective layers, whereas in FIG. 104 they are on lower faces of their respective layers. In FIG. 103, the active devices are on an upper face and the passive devices are on a lower face.

Naturally, certain configurations are preferable to others. The choice will depend upon numerous factors, most of which relate to thru-via technology and the number of pins that are available to connect the layers to external circuitry.

The passive device layer and active device layer can be in any form when attached. Two common choices would be in die or wafer form.

FIGS. 104-106 show cross-sections of two die-to-die arrangements in which an interconnect structure connects switches in an active die to capacitors on a passive die. In FIG. 104, the switches connect to a planar capacitor whereas in FIG. 106 the switches connect to a trench capacitor. The first bumps C4, which provide the electrical connections from the die stack to the printed-circuit board, and through-vias TV are omitted in FIGS. 104-106 but can be seen in FIGS. 107-108.

Although any kind of capacitor can be used, trench capacitors are preferable to planar capacitors because trench capacitors offer greater capacitance per unit of die area than planar capacitors, sometimes by one or two orders of magnitude. Additionally, trench capacitors offer lower equivalent series resistance than planar capacitors. Both of these capacitor attributes are desirable for use in power converters that use capacitive energy transfer because they affect the efficiency of the power converter.

As shown in FIGS. 104-106, an interconnect structure connects the switches on the active die to the capacitors on the passive die. This interconnect structure can be implemented in numerous ways. In the case of FIGS. 104-106, the interconnect structure is the union of a multilayer interconnect structure on the passive die, a single layer of second bumps C5, and a multilayer interconnect structure on the active die. The only requirements are that the interconnect structure connects the switches on one device layer to the capacitors on the other device layer, that the two device layers are stacked one on top of the other, and that the second bumps C5 have a much finer pitch than the first bumps C4. In some embodiments, the pitch of the second bumps C5 is four times greater than the pitch of the first bumps. As used herein, “pitch” means the number of bumps per unit length.

FIGS. 107-108 show another embodiment implemented by wafer-to-wafer stacking. In this embodiment, there is no need for the second bumps C5. Instead, the active and passive wafers electrically connect to each other using a bonding process. In FIG. 107, the device face of the active layer is its lower face and in FIG. 108, the device face of the active layer is its upper face. Examples of suitable bonding processes are copper-copper and oxide-oxide bonding. Furthermore, FIGS. 107-108 show the thru-vias and some of the first bumps C4, which were omitted in FIGS. 104-106.

A switched-capacitor power converter of the type discussed herein has a great many switches and capacitors in a switched-capacitor power converter. These all have to be interconnected correctly for the power converter to operate. There are many ways to physically lay out the conducting paths that interconnect these components. However, not all of these ways are equally efficient. Depending on their geometry, some of these conducting paths may introduce noticeable parasitic resistance and/or inductance. Because there are so many interconnections, it can be a daunting challenge to choose a set of interconnections that will both provide acceptable parasitic resistance and inductance for the power converter as a whole.

One method that can be used to control these parasitic quantities is to partition the switches and capacitors.

One way to reduce such parasitic quantities is to choose the shape and locations of the switches on the active layer so that they fit beneath the capacitors on the passive layer. This avoids forcing current to undertake a long journey along the faces of the layers as it travels between a switch and a capacitor. An example of this technique is shown in FIG. 110, in which eight switches S₁-S₈ and a controller 20A are disposed on an active layer that is located below a passive layer having two capacitors. Although the switches are not completely visible through the passive layer, their locations are marked by dotted lines on FIG. 110. The figure shows a first capacitor C₁ on top of switches S₁, S₂, S₅, S₆ and a second capacitor C₂ on top of switches S₃, S₄, S₇, S₈.

Another way to reduce such parasitic quantities arises from recognizing that switches in a switching network 12A are usually active devices that are implemented with transistors. The switching network 12A may be integrated on a single monolithic semiconductor substrate or on multiple monolithic semiconductor substrates, or formed using discrete devices. Furthermore, since the device is a power converter, each switch may be expected to carry a large amount of current. A switch that carries a great deal of current is often implemented by numerous current paths connected in parallel to a common terminal.

In a switch as described above, the current paths that make up the switch are physically located side-by-side and thus occupy a space having a non-zero width. These current paths all connect to a terminal that is itself connected to a conducting path. An example of this configuration is shown in FIG. 109 and FIG. 112. In particular, FIG. 112 shows a transistor on a first layer and a capacitor on a lower layer. The transistor has first, second, and third current paths with the second current path being between the first and third. The three current paths extend between one source terminal and one drain terminal of the transistor.

Some current entering the source terminal shown in FIG. 112 goes straight ahead into the second current path. But some of it turns left or right before turning again to proceed down the first and third current paths. At the other end of the transistor's channel, current that traversed the first and third current paths must again make a turn to reach the drain terminal. These currents are referred to as “lateral” current.

Similarly, the lower layer of FIG. 112 shows a capacitor that has three separate current paths connected to first and second capacitor terminals. In the course of being charged and discharged, some lateral current is inevitable for reasons discussed in connection with the transistor in the upper layer.

One way to reduce this lateral current is to partition the switches and the capacitors into numerous partitions, as shown in FIG. 109 and FIG. 113. This partitioning essentially involves converting an n-terminal device into an (n+m) terminal device where m depends on the number of partitions. Thus, after having been partitioned, the two-terminal capacitor of FIG. 112 is transformed into a six-terminal capacitor in FIG. 113. Similarly, the source terminal and drain terminal of the transistor in FIG. 112 is transformed into three source terminals and three drain terminals in the transistor of FIG. 113.

The difference between FIGS. 112 and 113 is that each current path in FIG. 113 has its own terminal. In contrast, in FIG. 112, all current paths share the same terminals. Thus, FIG. 112 shows three current paths connected in parallel, whereas FIG. 113 shows three current paths that are partitioned and therefore isolated from each other.

The three current paths shown collectively represent a switch on an active layer that is formed by various doping profiles along a piece of silicon to provide charge carriers and then connecting those three lines to a pair of external terminals, as shown in FIG. 112, or connecting each line to its own pair of external terminals, as shown in FIG. 113.

The capacitor represented by the lower layer of FIG. 112 is a two-terminal capacitor like any conventional capacitor. Prior art converters use capacitors of this type. However, unlike prior art converters, which use two-terminal capacitors, a converter as disclosed herein uses a six-terminal capacitor as shown FIG. 113. Although such a capacitor is more complex because it has more terminals that need to be both made and properly aligned, it reduces parasitic effects caused by lateral current.

Similarly, the transistor switch represented by the upper layer of FIG. 112 has one source terminal and one drain terminal. This is the kind of transistor that is used in conventional power converters. In contrast, the transistor represented by the upper layer of FIG. 113 has three source terminals and three drain terminals. Although such a transistor is more complex because it has more terminals that need to be both made and properly aligned, it reduces parasitic effects caused by lateral current.

It should be apparent that the act of partitioning is geometry-independent. Its essence is that of turning an n-terminal device into an (n+m) terminal device in an effort to reduce parasitic effects. There is no requirement that the device be oriented in any particular way. In particular, there is no requirement that the partitioning be carried out in only one dimension as shown in FIG. 113. For example, it is quite possible to partition a component along x and y directions as shown in the nine-partition switch of FIG. 111 and the six-partition capacitor shown in FIG. 114.

Both the techniques shown in FIG. 113 and FIG. 114 reduce the vertical and lateral distance between the active and passive devices while also providing a uniform current distribution to each individual switch and/or switched-capacitor cell. This tends to reduce the parasitic resistance and inductance of the connection between the switches and capacitors. This offers considerable advantages. Parasitic inductance limits the switching speed while parasitic resistance limits the efficiency of the power conversion process.

FIG. 115 shows a functional block diagram of the switching network 12A of FIGS. 13 and 12. The illustrated switching network 12A is a two-phase cascade multiplier that transforms a first voltage V1 into a second voltage V2. It does so by choreographing the flow of charge into and out of charge-transfer capacitors (also known as coupling capacitors) in a first charge-transfer capacitor set 50A.

Depending upon the type of capacitor, each charge-transfer capacitor may have a capacitance that is a function of the voltage across it. The charge-transfer capacitors are selected so that they all have the same capacitance at their respective operating voltages. However, at the same voltage, it may well be that the different charge-transfer capacitors will have different capacitances (e.g., MLCC have a strong capacitance dependence upon dc voltage bias).

The switching network 12A includes first and second phase-switch sets 54A, 54B, one for each phase. The switches within each phase-switch set 54A, 54B will be referred to herein as “phase switches.” Similarly, the switching network 12A includes first and second stack-switch sets 52A, 52B, again, one for each phase. The switches within each stack-switch set 52A, 52B will be referred to herein as “stack switches.”

Each of the switches takes up a certain amount of area on semiconductor substrate (e.g., silicon, GaAs, GaN, and SiC). The areas taken up by each switch need not be the same, however. In general, it is useful to have switches that are expected to carry considerable amounts of current be larger than those that carry less current. This permits the overall circuit to be smaller, while avoiding excessive conductive losses.

One or more of the switches can be partitioned to discourage lateral flow of current within the area defined by the switch. This can be carried out by having multiple terminals on each end of the switch. With such multiple terminals, current entering through any one terminal will be more likely to flow to a terminal directly opposite, thus reducing the extent of lateral current flow within the switch.

To control operation of the phase switches and the stack switches, the switching network 12A features two separate and distinct controllers: a phase controller 59A to control the phase switches and a stack controller 51 to control the stack switches.

The phase controller 59A controls the phase switches based at least in part on a phase-controller input signal I_(O1). It does so through a phase control path 55B that connects the phase controller 59A to the phase switches. Meanwhile, the stack controller 51 controls the stack switches based at least in part on a stack-controller input signal I_(O2). It does so through a stack control path 55A that connects the stack controller 51 to the stack switches. An inter-controller commissure 57 provides communication between the phase controller 59A and the stack controller 51. This permits the phase controller 59A and the stack controller 51 to control the phase switches and stack switches in a coordinated fashion rather than independently.

An advantage of the manufacturing procedures used in integrated circuits is the ability to integrate many components on a single die. This makes it easier to manufacture many components at once, and to thus reduce the manufacturing cost per component.

One way to manufacture the switching network 12A shown in FIG. 115 is to place the first and second stack-switch sets 52A, 52B and the first and second phase-switch sets 54A, 54B on the same die. Since only one die has to be manufactured, the cost of manufacture on a per switch basis would be expected to be reduced.

Because of their roles in the circuit, the stack switches and the phase switches have different requirements. In particular, the phase switches do not experience such high voltages or currents. As a result, the phase switches are relatively simple and inexpensive to manufacture. On the other hand, the stack switches are regularly exposed to fairly high voltage differences across them. Because of these special needs, the stack switches require different manufacturing steps.

The more complex procedure used to manufacture stack switches can be used to also manufacture phase switches. Thus, it is feasible to manufacture the first and second stack-switch sets 52A, 52B and the first and second phase-switch sets 54A, 54B on the same integrated circuit. This offers the advantage of having to carry out only one manufacturing procedure.

The switching network 12A shown in FIG. 115 avoids this advantage by having the first and second stack-switch sets 52A, 52B and the first and second phase-switch sets 54A, 54B be on different dies instead of on the same die. As a result, it becomes necessary to use two manufacturing steps instead of a single manufacture step.

Specifically, FIG. 115 shows a first phase-die 58A and a stack-die 56. The first phase-die 58A contains the first and second phase-switch sets 54A, 54B and the phase controller 59A. The stack-die 56 contains the first and second stack-switch sets 52A, 52B and the stack controller 51.

In some embodiments, one or both of the phase controller 59A and the stack controller 51 are also on separate controller dies, thus further increasing the number of separate manufacturing operations that must be carried out to construct the switching network 12A.

In the embodiment shown in FIG. 115, the first and second phase-switch sets 54A, 54B are both on the first phase-die 58A and the first and second stack-switch sets 52A, 52B are on a separate stack-die 56. Thus, each die is associated with both phases. However, it is also possible to place each phase on its own die.

For example, FIG. 116 shows a circuit that transforms a first voltage V₁ into a second voltage V₂, which it provides to the load 18A. The circuit has four separate dies: a first phase-die for the first phase-switch set 54A, a second phase-die for the second phase-switch set 54B, a first stack-die for the first stack-switch set 52A, and a fourth stack-die for the second stack-switch set 52B. In this embodiment, the first phase-switch set 54A and the first stack-die are associated with the first phase, and the second phase-switch set 54B and the second stack-switch set 52B are associated with the second phase.

In FIG. 116, the phase controller 59A and the stack controller 51 have been omitted to promote clarity. The switches are also shown schematically instead of as transistors. Had they been shown as transistors, the phase controller 59A and the stack controller 51 would connect to the gate terminals of those transistors.

The first phase-switch set 54A in FIG. 115 corresponds to first and second phase switches S_(P1), S_(P2) in FIG. 116. The second phase-switch set 54B in FIG. 115 correspond to third and fourth switches S_(P3), S_(P4) in FIG. 116. These are placed together on the same first phase-die 58A in FIG. 115.

The first stack-switch set 52A in FIG. 115 corresponds to the switches S_(1A), S_(2A), S_(3A), S_(4A) in FIG. 116. The second stack-switches 52B in FIG. 115 correspond to the switches S_(1B), S_(2B), S_(3B), S_(4B) in FIG. 116. These are all placed together on the same stack-die 56 in FIG. 115.

In connecting the various switches to the corresponding charge-transfer capacitors C_(1A), C_(2A), C_(3A), C_(4A), C_(1B), C_(2B), C_(3B), C_(4B) of the first charge-transfer capacitor set 50A, it is useful to avoid excessive path lengths between the charge-transfer capacitors C_(1A), C_(2A), C_(3A), C_(4A), C_(1B), C_(2B), C_(3B), C_(4B) and the stack switches S_(1A), S_(2A), S_(3A), S_(4A), S_(1B), S_(2B), S_(3B), S_(4B), S_(P1), S_(P2), S_(P3), S_(P4). Excessive path lengths are undesirable because they increase resistance between components. These path lengths can be reduced by suitably arranging the dies and the locations of the terminals on each die.

FIG. 117 shows a particular implementation of terminals on the stack-die 56 and terminals on the first phase-die 58A for the embodiment shown in FIG. 115. Charge-transfer capacitors from the first charge-transfer capacitor set 50A extend between the stack-die 56 and the first phase-die 58A. The terminals shown in FIG. 116 have been configured so that those that connect to the positive terminals of the charge-transfer capacitors are all on one side and those that connect to the negative terminals of the charge-transfer capacitors are all on the other side. This reduces path length between the stack switches, the phase switches, and the charge-transfer capacitors.

As shown in FIG. 115, both the stack-die 56 and the first phase-die 58A connect to the output of the switching network 12A. In FIG. 117, a conducting interdie commissure 63 of length Y1 connects the output terminal of the switching network 12A to both the stack-die 56 and the first phase-die 58A. This length Y₁ is tuned to the length of the capacitors in the first charge-transfer capacitor set 50A.

The embodiment shown in FIG. 117 results in the stack-die 56 being coplanar with the first phase-die 58A. However, it is possible to further reduce conducting path lengths by having the stack-die 56 and first phase-die 58A on different planes. This can be achieved by folding the layout shown in FIG. 117 about a vertical line extending down the middle of the interdie commissure 63. Alternatively, it is possible to have different phases on different levels by folding along a horizontal axis of symmetry.

In the embodiment of FIG. 116, each charge-transfer capacitor C_(1A), C_(2A), C_(3A), C_(4A), C_(1B), C_(2B), C_(3B), C_(4B) will at some point be connected to the first phase-switch set 54A and to the second phase-switch set 54B. It is possible, however, to arrange the components to form a switching network 12A that has first and second charge-transfer capacitor sets 50A, 50B, each of which connects to only one of the first and second phase-switch sets 54A, 54B. An example of this topology can be seen in FIG. 118.

FIG. 118 shows a functional block diagram of a two-phase switching network 12A that transforms a first voltage V₁ into a second voltage V₂. It does so by choreographing the flow of charge into and out of charge-transfer capacitors.

The switching network 12A of FIG. 118 has first and second phase-switch sets 53A, 53B, one for each phase, and first and second stack-switch sets 52A, 52B, one for each phase. To control operation of these switches, the switching network 12A features three separate and distinct controllers: a first phase-controller 59A to control phase switches in the first phase-switch set 53A, a stack controller 51 to control stack switches in the first and second stack-switch sets 52A, 52B, and a second phase-controller 59B to control phase switches in the second phase-switch set 53B.

The first phase-controller 59A controls the operation of the phase switches in the first phase-switch set 53A based in part on a first-phase-controller input signal I_(O1). It does so through a first phase-control path 55B that connects the phase controller 59A to the phase switches. The second phase-controller 59B controls the operation of the phase switches in the second phase-switch set 53B based at least in part on a second-phase-controller input signal IO₃. It does so through a second phase-control path 55C that connects the second phase controller 59B to the second phase-switch set 53B.

The stack controller 51 receives a stack-control input signal I_(O2) and uses that to control the operation of the stack switches in the first and second stack-switch sets 52A, 52B. It does so via a stack control path 55A. The first phase-controller 59A, the second phase-controller 59B, and the stack controller 51 all communicate via an inter-controller commissure 57.

FIG. 119 shows a circuit with four separate dies: a first phase-die for the first phase-switch set 53A, a second phase-die for the second phase-switch set 53B, a first stack-die for the first stack-switch set 52A, and a fourth stack-die for the second stack-switch set 52B.

In this embodiment, the first phase-switch set 54A and the first stack-die are associated with the first phase, and the second phase-switch set 54B and the second stack-switch set 52B are associated with the second phase. The first and second phase-controllers 59A, 59B and the stack controller 51 have been omitted to promote clarity. The switches are also shown schematically instead of as transistors.

The circuit shown in FIG. 119 includes a voltage source 14 and a load 18A. The voltage source 14 provides the first voltage V₁ in FIG. 118. The load 18A connects to the second voltage V₂ in FIG. 118.

The first phase-switch set 53A in FIG. 118 corresponds to first, second, third, and fourth phase switches S_(P1), S_(P2), S_(P3), S_(P4) in FIG. 119. The second phase-switch set 53B correspond to fifth, sixth, seventh, and eighth switches S_(P5), S_(P5), S_(P7), S_(P8) in FIG. 119. These are placed on first and second phase-dies 58A, 58B in FIG. 118.

The first stack-switch 52A in FIG. 118 corresponds to the first, second, third, fourth, and fifth switches S_(1A), S_(2A), S_(3A), S_(4A), S_(5A) in FIG. 119. The second stack switches 52B in FIG. 118 correspond to the sixth, seventh, eighth, ninth, and tenth switches S_(1B), S_(2B), S_(3B), S_(4B), S_(5B) in FIG. 119. These are all placed together on the same stack-die 56 in FIG. 118.

FIG. 120 shows a particular implementation of terminals on the stack-die 56, terminals on the second phase-die 58B, and the charge-transfer capacitors C_(1B), C_(2B), C_(3B), C_(4B) for the switching network 12A shown in FIG. 118. The locations at which the phase switches S_(P5), S_(P6), S_(P7), S_(P8) from the second phase-switch set 53B connect to the terminals of the second phase-die 58B can be seen in FIG. 121.

The terminals on the second phase-die 58B are laid out in a manner similar to that shown for the first phase-die 58A and have thus been omitted for clarity. Similarly, the interconnections between the charge-transfer capacitors C_(1A), C_(2A), C_(3A), C_(4A) and both the stack-die 56 and the first phase-die 58A are similar to those shown in FIG. 120 and are omitted for clarity.

Referring back to FIG. 120, an interdie commissure 63 again connects the second phase-switch die 58B to the stack-die 56. The interdie commissure 63 has a bridge section having a length Y₂ that depends on the physical size of the charge-transfer capacitors C_(1B), C_(2B), C_(3B), C_(4B) from the second charge-transfer capacitor set 50B. The dimensions of the interdie commissure 63 are enlarged at selected locations to avoid excessive build-up of current density. As a result, the interdie commissure 63 is wider at locations where considerable current is expected to flow, but narrower at locations where smaller currents are expected to flow. This avoids having an excessively large footprint while also avoiding resistive losses.

In many cases, the switching network 12A is to be connected to a regulator (also known as regulating circuit). Under these circumstances, it is useful to include a regulator-switch set 65 within the phase-die 58C as shown in FIG. 122. It is expedient to integrate the first and second phase-switch sets 54A, 54B and the regulator-switch set 65 in the phase-die 58C since the regulator switches and the phase switches have similar performance requirements. Both the phase switches and the regulator switches are intended to sustain essentially the same voltage. As such, the same manufacturing process can be used for both kinds of switch.

The regulator that is to be coupled to the regulator-switch set 65 introduces an inductive load, which in turn introduces considerable noise in the substrate of any die that contains the regulator-switch set 65. Since, during operation, the substrate of the phase-die 58C is inherently noisier than the substrate of the stack-die 56, it is advantageous to include the regulator-switch set 65 in the phase-die 58C so that operation of the stack-die 56 can proceed with minimal disturbance due to electrical noise.

In the embodiment shown in FIG. 122, the phase controller is replaced by a hybrid controller 59C configured to control both the regulator-switch set 65 and the phase-switch set 54A, 54B via a phase control path 55B, which extends from the hybrid controller 59C to the phase-switch set 54A, 54B, and a regulator control path 55D, which extends from the hybrid controller 59C to the regulator-switch set 65.

An advantage of placing the phase switches and stack switches on separate dies instead of integrating them into the same die is that doing so reduces the area of the die that holds the stack switches. Since this die must undergo a more expensive manufacturing process, and since the manufacturing cost is a function of die area, it is advantageous to reduce the die area. Since only the stack switches actually require the more expensive manufacturing process, it is advantageous to omit the phase switches and to place them on a separate die, which can then be manufactured more inexpensively.

Another advantage that arises is that having stack switches and phase switches on separate dies provides more flexibility in routing between components. This is because when all the components are on the same die, the components and the interconnections are confined to a two-dimensional space. In contrast, when a third dimension becomes available, there is an extra degree of freedom that can be used to optimize placement of the dies relative to each other to minimize path lengths.

FIGS. 123-128 collectively illustrate the flexibility associated with having a separate phase-die 58 and stack-die 56.

FIG. 123 shows a substrate 28 supporting charge-transfer capacitors C_(1A), C_(2A), a first die U₁ and a second die U₂. In the embodiment shown, the first die U1 corresponds to the stack-die 56 and the second die U₂ corresponds to the phase-die 58. The first and second dies U₁, U₂ are side-by-side with their respective device faces both facing the substrate 28. Electrically-conductive bumps 45 provide electrical communication between the first and second dies U₁, U₂ and the charge-transfer capacitors C_(1A), C_(2A).

FIG. 124 shows a substrate 28 supporting charge-transfer capacitors C_(1A), C_(2A), a first die U₁, and a second die U₂. The first and second dies U₁, U₂ are side-by-side inside a package 82 with their respective device faces both facing the substrate 28. Within the package 82, a first electrical interconnect layer 43A provides interconnection between the first and second dies U₁, U₂. Electrically-conductive bumps 45 provide electrical communication between the package 82 and the charge-transfer capacitors C_(1A), C_(2A).

FIG. 125 shows the substrate 28 supporting a package 82 in which the second die U₂ is stacked on top of the first die U₁. A first interconnect layer 43A connects the first die U₁ with the rest of the switching network 12A and a second interconnect layer 43B connects the second die U₂ with the rest of the switching network 12A. Electrically-conductive bumps 45 provide electrical communication between the package 82 and the charge-transfer capacitors C_(1A), C_(2A).

FIG. 126 shows the substrate 28 supporting a package 82 having a passive device layer 41A and an active device layer 42A. The charge-transfer capacitors C_(1A)-C_(4B) are integrated into their own capacitor die 81, which is in the passive device layer 41A. The first and second dies U₁, U₂ are in the active device layer 42A. In this embodiment, the passive device layer 41A can be viewed as a charge-transfer layer and the active device layer 42A can be viewed as a switching layer. Electrically-conductive bumps 45 provide electrical communication between the package 82 and any external components.

FIG. 127 shows the substrate 28 supporting a package 82 having a mixed device layer 40A, which is a hybrid layer that serves as both a switching layer and a charge-transfer layer, and an active device layer 42A, which is only a switching layer. The charge-transfer capacitors C_(1A)-C_(4B) are integrated into their own capacitor die 81, which is in the mixed device layer 40A, along with the second die U₂. The first die U₁ is in the active device layer 42A, but laterally offset from the second die U₂. This provides a shorter path length for connections between the first and second dies U₁, U₂. Electrically-conductive bumps 45 provide electrical communication between the package 82 and any external components.

Yet another advantage of having the various components of a switched-capacitor circuit be on separate dies is that doing so can promote heat dissipation. This is because there will be more surface area available to radiate heat. The ability to efficiently dissipate heat is particularly important for a power converter, since a power converter has a tendency to run hot. An example of how to arrange dies to promote cooling is shown in FIG. 128.

FIG. 128 shows the substrate 28 supporting a package 82 having a first active device layer 42A, a second active device layer 42B, and a passive device layer 41A between the first active device layer 42A and the second active device layer 42B. The charge-transfer capacitors C_(1A)-C_(4B) are integrated into their own capacitor die 81, which is in the passive device layer 41A. The second die U₂ is in the second active device layer 42B and the first die U₁ is in the first active device layer 42A. In this embodiment, the passive device layer 41A is the charge-transfer layer and the first and second active device layers 42A, 42B are both switching layers. Electrically-conductive bumps 45 provide electrical communication between the package 82 and any external components.

An advantage of the embodiment shown in FIG. 128 is that the hottest components of the circuit, namely the active device layers 42A, 42B, are outside, whereas the passive device layer 41A, which stays cooler, is in the inside. This configuration thus promotes cooling.

FIG. 129 shows the substrate 28 supporting an inductor L₁ and a package 82 having a passive device layer 41A and an active device layer 42A. Charge-transfer capacitors C_(1A), C_(2A) are disposed in the passive device layer 41A. The charge-transfer capacitors C_(1A), C_(2A) are discrete elements that, in some embodiments, are surrounded by a matrix 74 to mechanically support them. The first die U₁ is in the active device layer 42A with its device face facing electrically conductive bumps 45 that provide electrical communication between the package 82 and external components, including the inductor L₁. In this embodiment, the passive device layer 41A is the charge-transfer layer and the active device layer 42A is the switching layer. First and second interconnect layers 43A, 43B provide electrical communication between the charge-transfer capacitors C_(1A), C_(2A) and the first die U₁.

FIG. 130 shows the substrate 28 supporting an inductor L₁ and a package 82. The package 82 has a passive device layer 41A and an active device layer 42A. A first interconnect layer 43A resting on electrically-conductive bumps 45 provides electrical communication between the package 82 and external components, including the inductor L₁. Charge-transfer capacitors C_(1A), C_(2A) are disposed in the passive device layer 41A. These charge-transfer capacitors C_(1A), C_(2A) are discrete elements that, in some embodiments, are surrounded by a matrix 74 to mechanically support them. The first die U₁ is in the active device layer 42A with its device face facing a second interconnect layer 43B at the passive device layer 41A. The switching layer thus corresponds to the active device layer 42A and the charge-transfer layer is the passive device layer 41A. The second interconnect layer 43B provides electrical communication between the first die U₁ and the charge-transfer capacitors C_(1A), C_(2A). A heatsink 76 opposite the device face contacts thermally-conductive bumps 46. Unlike the electrically-conductive bumps 45, which conduct both heat and electricity, the thermally-conductive bumps 46 are dedicated to heat transfer only.

FIG. 131 shows the substrate 28 supporting an inductor L1 and a package 82. The package 82 has a passive device layer 41A, which serves as the charge-transfer layer, and an active device layer 42A, which serves as a switching layer. A first interconnect layer 43A rests on an electrically-conductive pad 45B. This first interconnect layer 43A provides electrical communication between the package 82 and external components, including the inductor L₁. Charge-transfer capacitors C_(1A), C_(2A) are disposed in the passive device layer 41A. These charge-transfer capacitors C_(1A), C_(2A) are discrete elements that, in some embodiments, are surrounded by a matrix 74 to mechanically support them. The first die U₁ is in the active device layer 42A with its device face facing a second interconnect layer 43B at the passive device layer 41A. This second interconnect layer 43B provides electrical communication between the first die U₁ and the charge-transfer capacitors C_(1A), C_(2A). A heatsink 76 opposite the device face contacts a thermally-conductive pad 46B. Unlike the electrically-conductive pad 45B, which conducts both heat and electricity, the thermally-conductive pad 46B is dedicated to heat transfer only.

FIG. 132 shows the substrate 28 supporting a package 82 having a passive device layer 41A and an active device layer 42A. The pass device layer 41A serves as the charge-transfer layer, and the active device layer 42A serves as a switching layer. A first interconnect layer 43A resting on electrically-conductive bumps 45 provides electrical communication between the package 82 and external components. An inductor L₁ and charge-transfer capacitors C_(1A), C_(2A) are disposed in the passive device layer 41A. These are discrete elements that, in some embodiments, are surrounded by a matrix 74 to mechanically support them. The first die U₁ is in the active device layer 42A with its device face facing a second interconnect layer 43B at the passive device layer 41A. This second interconnect layer 43B provides electrical communication between the first die U₁, the charge-transfer capacitors C_(1A), C_(2A), and the inductor L₁. A heatsink 76 opposite the device face contacts thermally-conductive bumps 46. Unlike the electrically-conductive bumps 45, which conduct both heat and electricity, the thermally-conductive bumps 46 are dedicated to heat transfer only.

FIG. 133 shows the substrate 28 supporting a package 82 having a passive device layer 41A and a mixed device layer 40A. The passive device layer 41A serves as the charge-transfer layer, and the mixed device layer 40A serves as a switching layer. A first interconnect layer 43A resting on electrically-conductive bumps 45 provides electrical communication between the package 82 and external components. Charge-transfer capacitors C_(1A), C_(2A) are disposed in the passive device layer 41A. These are discrete elements that, in some embodiments, are surrounded by a matrix 74 to mechanically support them. An inductor L₁ and the first die U₁ are side-by-side in the mixed device layer 40A. The inductor L₁ is formed by metallic traces wound around a core in the mixed device layer 40A. The first die U₁ has its device face facing a second interconnect layer 43B at the passive device layer 41A. This second interconnect layer 43B provides electrical communication between the first die U₁, the charge-transfer capacitors C_(1A), C_(2A), and the inductor L₁. A heatsink 76 opposite the device face contacts thermally-conductive bumps 46. Unlike the electrically-conductive bumps 45, which conduct both heat and electricity, the thermally-conductive bumps 46 are dedicated to heat transfer only.

Another advantage of using different dies to build a switching network 12A is that come components are not good neighbors on the same die.

Since all components on a die share a common substrate, all components are inherently coupled. This means that activity at one end of the die may significantly affect activity at the other end of the die.

The stack switches handle considerable amounts of power. As a result, the stack switches do not always make good neighbors on the same die. In particular, when the stack switches and phase switches are on the same die, the phase switch operation can be adversely affected by stack switch operation.

In some embodiments, the stack controller 51 is integrated into the stack-die. This reduces overall pin count and also avoids the need to fabricate a separate die. However, the very high currents associated with the operation of the stack switches may interfere with operation of the stack controller 51, both because of EMI and because of electrical coupling. Thus, in some embodiments, the stack controller 51 is on a separate die.

Among other advantages, the arrangements described above avoid the component and pin count penalty, reduce the energy loss in the parasitic interconnect structures, and reduces the total footprint of power converters that use capacitors to transfer energy.

In some implementations, a computer accessible storage medium includes a database representative of one or more components of the converter. For example, the database may include data representative of a switching network that has been optimized to promote low-loss operation of a charge pump.

Generally speaking, a computer accessible storage medium may include any non-transitory storage media accessible by a computer during use to provide instructions and/or data to the computer. For example, a computer accessible storage medium may include storage media such as magnetic or optical disks and semiconductor memories.

Generally, a database representative of the system may be a database or other data structure that can be read by a program and used, directly or indirectly, to fabricate the hardware comprising the system. For example, the database may be a behavioral-level description or register-transfer level (RTL) description of the hardware functionality in a high level design language (HDL) such as Verilog or VHDL. The description may be read by a synthesis tool that may synthesize the description to produce a netlist comprising a list of gates from a synthesis library. The netlist comprises a set of gates that also represent the functionality of the hardware comprising the system. The netlist may then be placed and routed to produce a data set describing geometric shapes to be applied to masks. The masks may then be used in various semiconductor fabrication steps to produce a semiconductor circuit or circuits corresponding to the system. In other examples, Alternatively, the database may itself be the netlist (with or without the synthesis library) or the data set.

Having described one or more preferred embodiments, it will be apparent to those of ordinary skill in the art that other embodiments incorporating these circuits, techniques and concepts may be used. Accordingly, it is submitted that the scope of the patent should not be limited to the described embodiments, but rather, should be limited only by the spirit and scope of the appended claims. 

1-12. (canceled)
 13. An apparatus for power conversion, the apparatus comprising: a plurality of switches configured to facilitate operation of a switched-capacitor converter, the switches being configured to switch between a first state and a second state to transition a switched-capacitor network of the switched-capacitor converter between a first and a second switch arrangements, wherein the plurality of switches comprises one or more phase switches and one or more stack switches; a controller configured to receive one or more feedback signals from one or more terminals of the switched-capacitor converter, the one or more feedback signals being indicative of the operation of the switched-capacitor converter; and a first die and a second die configured according to a first configuration or a second configuration, wherein, in the first configuration, the one or more phase switches are on the first die and the one or more stack switches are on the second die, and in the second configuration, the controller is on the first die and a particular switch of the plurality of switches is on the second die.
 14. The apparatus of claim 13, wherein the plurality of switches are controllable to switch between the first state and the second state at a switching frequency to facilitate zero current switching (ZCS) of one or more switches of the plurality of switches.
 15. The apparatus of claim 13, wherein the controller is configured to output one or more control signals to open the plurality of switches during a dead-time interval of the switched-capacitor network.
 16. The apparatus of claim 13, wherein the controller comprises a first feedback loop to output a first control signal for controlling an intermediate voltage.
 17. The apparatus of claim 16, wherein the one or more feedback signals comprise a first feedback signal indicative of the intermediate voltage and a second feedback signal indicative of an input voltage, and the controller is configured to output the first control signal according to the first feedback signal and the second feedback signal.
 18. The apparatus of claim 16, wherein the controller comprises a second feedback loop to output a second control signal for controlling an output voltage, and the second feedback loop is coupled to the first feedback loop.
 19. The apparatus of claim 18, wherein the second control signal is configured to serve as a gate drive to drive a gate terminal of a transistor in a regulating circuit connected to the switched-capacitor network.
 20. The apparatus of claim 18, wherein the one or more feedback signals further comprise a third feedback signal indicative of the output voltage, and the controller is configured to control the output voltage according to the third feedback signal and a reference signal.
 21. The apparatus of claim 18, wherein the first feedback loop and the second feedback loop are on the same die.
 22. The apparatus of claim 18, wherein the first feedback loop and the second feedback loop are on different dies.
 23. The apparatus of claim 13, further comprises an inductor connected to the switched-capacitor network, wherein the inductor sustains a peak-to-peak voltage ripple and supports an inductor current flowing through the inductor in operation at a particular switching frequency, the inductor current defining an average inductor current.
 24. The apparatus of claim 23, wherein the inductor current is a rectified sinusoidal current.
 25. The apparatus of claim 23, wherein an inductance of the inductor is proportional to a value selected by dividing the peak-to-peak voltage ripple by a product of the average inductor current and a switching frequency.
 26. The apparatus of claim 25, wherein a constant of proportionality by which the value is multiplied to obtain the inductance is 13/24.
 27. The apparatus of claim 13, wherein the particular switch comprises at least one phase switch or at least one stack switch.
 28. The apparatus of claim 13, wherein the switched-capacitor network further comprises: a first controller, a second controller, and an inter-controller commissure, wherein the first controller is configured to control the one or more phase switches on the first die, wherein the second controller is configured to control the one or more stack switches on the second die, wherein the inter-controller commissure provides a link between the first controller and the second controller to permit operation of the one or more phase switches on the first die that depends at least in part on operation of the one or more stack switches on the second die, and to permit operation of the one or more stack switches on the second die that depends at least in part on operation of the one or more phase switches on the first die.
 29. The apparatus of claim 28, wherein the first controller is on the first die and wherein the second controller is on the second die, and wherein the inter-controller commissure extends between the first die and the second die.
 30. The apparatus of claim 28, further comprising a third die and a fourth die, wherein the first controller is on the third die and wherein the second controller is on the fourth die, and wherein the inter-controller commissure extends between the third die and the fourth die.
 31. The apparatus of claim 13, wherein the switched-capacitor converter is a two-phase converter, wherein the apparatus further comprises a third die and a fourth die, wherein the one or more stack switches comprise a first set of stack switches and a second set of stack switches, each of which is associated with one of the two phases, wherein the first set of stack switches is on the second die and the second set of stack switches is on the fourth die, wherein the one or more phase switches comprise a first set of phase switches and a second set of phase switches, each of which is associated with one of the two phases, and wherein the first set of phase switches is on the first die and the second set of phase switches is on the third die.
 32. An apparatus for power conversion, the apparatus comprising: a switching network to transform a first voltage into a second voltage, the switching network to include a plurality of switches controllable to switch between a first state and a second state at a switching frequency; a controller to generate one or more signals for one or more switches of the plurality of switches to facilitate one or more transitions of the switching network between at least a first and a second switching arrangements; and a filter to couple the switching network to at least one regulating circuit, wherein the switching frequency facilitates zero current switching (ZCS) of the one or more switches of the plurality of switches.
 33. The apparatus of claim 32, wherein the apparatus comprises a plurality of switching networks, and wherein the filter is to couple the plurality of switching networks to the at least one regulating circuit.
 34. The apparatus of claim 32, wherein the switching network is to be coupled with the filter in series.
 35. The apparatus of claim 32, wherein the filter comprises an inductor.
 36. The apparatus of claim 32, wherein the filter comprises an LC filter.
 37. The apparatus of claim 32, wherein the filter is configured to connect the switching network to two or more regulating circuits.
 38. The apparatus of claim 32, further comprising: a plurality of regulating circuits, wherein the filter is configured to connect the switching network to all of the regulating circuits.
 39. An apparatus for power conversion, the apparatus comprising: a transformation stage comprising a switched-capacitor network to include a plurality of capacitors to be alternately coupled to a first group of switches or to a second group of switches controllable to respectively implement one or more switching arrangements via one or more switching frequencies so as to transform a first voltage into a second voltage at a shared node, the plurality of capacitors comprising a plurality of first capacitors connected to each other at a first node, and a plurality of second capacitors connected to each other at a second node; and a discrete inductor to be arranged to facilitate charging or discharging of the plurality of capacitors at respective charge or discharge rates during operation of the switched-capacitor network, wherein a filter including the discrete inductor is connected to the switched-capacitor network at the shared node, wherein at least some of the plurality of capacitors are coupled via the shared node during operation of the switched-capacitor network, wherein the filter is to connect the transformation stage to a load via the shared node, and wherein the one or more switching frequencies include a frequency to facilitate zero current switching (ZCS) of at least some switches of the first group of switches or the second group of switches; wherein in a first switching arrangement, the first capacitors are charged while the second capacitors are discharged, and in a second switching arrangement, the first capacitors are discharged while the second capacitors are charged.
 40. The apparatus of claim 39, wherein one or more capacitors of the plurality of capacitors to have capacitances being a function of voltage applied across the one or more capacitors.
 41. The apparatus of claim 39, wherein at least some of the plurality of capacitors to have substantially the same capacitance while at their respective maximum voltages.
 42. The apparatus of claim 39, wherein the plurality of capacitors comprise discrete capacitors.
 43. The apparatus of claim 39, wherein the charge or discharge rates is constrained by the discrete inductor. 